CH711341A2 - Footwear with ventilator. - Google Patents

Abstract

The invention relates to a footwear (10) with a ventilation device (34) which can be actuated by the foot when walking. The footwear (10) has a shoe sole and a top (14) connected thereto, the shoe sole consisting of a flexible sole portion and a more rigid heel portion (24) covered by an insole. The ventilation device (34) has an air pump, which is arranged in an air chamber (30). A suction port of the air pump is connected to a disposable suction valve and a discharge port of the air pump is connected to a one-way pressure valve. The ventilation openings of the insole are formed in the trunk area of the toes. The ventilation device (34) has a one-armed lever whose front end is fastened to the shoe sole, but whose rear end is in an actuating connection with the air pump.

Description

The invention relates to a footwear according to the preamble of claim 1. The invention relates, in particular work, sports and winter shoes, in which his shoe sole is provided with a ventilation device for ventilation of the shoe interior. Such a ventilation device is installed in a flexible shoe sole and covered by an insole. This ventilation device and is operated during the walking movement by the foot movement, or the weight load.

As is known, the conventional footwear has a significant disadvantage. As a person's foot sweats, especially during work, sports and winter shoes, the person becomes too tired during a walking movement and a bad foot odor develops. There were approaches by appropriate ventilation of the shoe using a ventilation device to eliminate this disadvantage.

Insoles for footwear are known in large numbers. Thus, e.g. CH 306 358 describes a shoe sole which has ribs extending transversely to the sole, so that cavities form, which mainly serve to develop the climate in the shoe. Through the individual cavities, the air circulates during the foot movement, so that the foot is ventilated and the interior of the shoe drained. The accumulated moisture is partially conveyed to the outside during the walking movement by the alternating compression and again expansion of the cavities.

From WO 95/13715 A1 a further shoe sole with a ventilation system is known. This document describes a valve construction for introducing air into the air space between the shoe sole and insole. In doing so, the air is introduced into an inlet valve from inside the shoe, i. from the heel section of the foot, sucked. When placing the heel, the air inlet openings are closed by means of check valves forming valve tongues, and the elastically deformable pump chamber or the air chamber is compressed by the pressure load of the human heel, whereby the air is pressed through the air outlet openings in the air ducts. The air then passes through the toe or ball area permeable insole in the shoe.

Although this solution is suitable to develop a corresponding air cushion between the outsole and the insole, it provides experience but insufficient ventilation. This is due to the fact that due to the unfavorable arrangement of the suction between the steps from the corner only relatively small amount of air can flow into the air chamber. On the other hand, the air chamber can be formed only with too small a volume. Further, the sole must be made of multiple layers since the check valve of the air chamber is disposed inside the shoe sole, thereby complicating the formation of the shoe sole and increasing the cost of manufacturing technology.

From DE 7 802 213 U1 a similar insole with a ventilation system is known in which air flows through air inlet openings in the heel area in a compressible by compressive air chamber, which communicates with another air chamber in the toe and ball area. When placing the heel, the air inlet openings are closed, compressed the air chamber and the air in the air chamber transported through the air in the toe and ball outlet openings in the shoe interior. In order for the air in the insole to be carried only from the heel area towards the toe area, check valves are provided which are located at the air inlet openings, air outlet openings and / or inside the insole between the chambers. The known check valves are formed in the simplest embodiment of glued inside the air chamber flaps.

The disadvantage of these check valves that they are incomplete leak at low air currents in the reverse direction, since the flaps are not held by a spring or the like on the openings. However, an absolute tightness even with small air flows is important, especially in the area of the air inlet openings, so that even at the beginning of the compression process, no air could escape from the air chamber and the pumping process would be effectively carried out.

The object of the present invention is therefore to provide a developed footwear with a ventilation system, which does not have the aforementioned disadvantages and in particular has a functionally reliable and particularly simple and inexpensive construction. The price of such shoes should not exceed the normal selling price of the shoes. Another object of the present invention is to positively influence the human organism via the foot sole of the footwear.

Furthermore, with the invention, the ventilation of the foot to be made possible in a hygienic manner, at the highest possible levels of wearing comfort of shoes with such sole.

The objects are achieved by the features of independent claims 1 and 5. Advantageous developments are set forth in the figures and in the dependent claims.

After the first shoe according to the invention, the footwear has a shoe sole and, associated, especially closed shell. The shoe sole consists of a flexible sole part and a more rigid heel part and is covered by an insole. The shoe sole is associated with a ventilation device actuated when walking through the foot of a shoe wearer, wherein at least one air chamber of the ventilation device is formed in the shoe sole. The ventilation device is provided with a one-way suction valve which fills the air chamber with air and one which supplies the compressed air of the air chamber as the ventilation air flow into the foot space of the footwear through the ventilation openings of the insole-promoting one-way pressure valve.

The ventilation device has an air pump, which is arranged in the air chamber, wherein a suction nozzle of the air pump with the disposable suction valve and a discharge nozzle of the air pump are connected airtight with the one-way pressure valve. The ventilation openings of the insole are formed in the trunk area of the toes. The disposable suction valve is arranged so that the air pump can be charged with fresh air from the ball area of the footwell. The actuated when walking through the foot of a shoe wearer ventilation device further has a, preferably made of steel, one-armed lever whose front end to the shoe sole, preferably in Schuhnasebereich (in the front area of the footwear) is attached, the rear end, however, with the air pump is in operative connection.

According to a further feature of the invention, the air chamber in the heel part is formed as a horseshoe-shaped cavity, preferably has a middle support rib, preferably in the recess, the compression unit can be arranged and fixed.

Preferably, the air pump is designed as a flexible diaphragm pump with a rigid cover plate.

The shoe sole can be made of one piece, preferably of rubber or plastic, e.g. Polyurethane are produced.

In a further footwear according to the invention, the flexible shoe sole is optionally formed multi-layered, wherein at least a part thereof, preferably an intermediate layer, made of a plastic, in particular polyurethane. The density and elasticity of the plastic, in particular polyurethane, is determined in each case in function of a weight load according to the body weight of the respective shoe wearer so that the volume change of the air chamber in the shoe sole, achieved by a compression, preferably in the intermediate layer, for producing a predetermined value Cooling air flow is maintained. The vents of the ventilation device actuated by the movement of the foot while walking are provided in the insole at the stem area of the toes. The disposable suction valve is arranged in the air chamber and can be filled with air from the ball area of the footwear.

Optionally, the shoe sole may have a multi-layer structure, which preferably consists of an outer running layer of rubber, an intermediate layer of plastic, in particular polyurethane, and an inner insole.

The ventilation device may be provided in addition to the primary air chamber with additional air chambers, preferably designed as a cylinder secondary air chambers, which are physically separated from the primary air chamber airtight. The secondary air chambers are advantageously formed in the intermediate layer.

Optionally, at least one of the cylinder formed as secondary air chambers may be connected by slots with the air space of the primary air chamber.

The ventilation device is in some embodiments with additional, airtight from the primary air chambers separated tertiary air chambers, preferably air springs, provided, which are also in the shoe sole, preferably in the intermediate layer formed.

According to a further important feature of the invention is also the volume of the primary air chamber, and the volume and the number of secondary and / or tertiary air chambers and the material density and flexibility of the shoe sole, preferably the intermediate layer, depending on the weight load according to the Body weight of the respective footwear wearer determined.

It is advantageous if a deodorant filling is arranged in the air chamber.

The one-way valves are preferably designed so that they can easily be inserted in the valve seats formed in the sole. As a result, the manufacturing process is considerably simplified and it is also an integral design of the soles possible. As a result, the shoe soles can have the same flexibility over the entire surface or this can also be controlled during manufacture. A non-return valve, which consists of a valve tongue which, in the unloaded state of the valve, bears in a sealing manner against a hole to be closed, shows a reliable blocking effect even with the slightest return flows. The elastic valve tongue, which rests on the opening due to its own material tension, can also adapt to deformed sole bodies, so that the ventilation system continues to work effectively even if the sole of the shoe deforms.

The attached to the opening sole member, vulcanized or welded valve tongue united in both valve body and valve spring and a joint for the valve body. If the bearing surface for the valve tongue has a concave curvature, the deformation of the valve tongue alone causes a constant surface pressure and thus good tightness. This also if the sole is deformed while walking. Due to the radius of curvature of the support surface can be adjusted in a certain range of contact pressure.

The valve tongue may be held in a holding device which is part of the sole material. Also, the valve tongue itself may be part of the shoe sole or consist of the same material as the shoe sole. Such a shoe sole, in which no additional materials are used, is easily recyclable.

Further advantages, features and details of the invention will become apparent from the following description in which with reference to the drawings, embodiments of the invention are described. The features mentioned in the claims and in the description may each be essential to the invention individually or in any desired combination.

The list of reference numerals as well as the technical content of the claims and figures are part of the disclosure. The figures are described coherently and comprehensively. The same reference symbols denote the same components, reference symbols with different indices indicate functionally identical or similar components.

It shows:

[0028] <Tb> FIG. 1 <SEP> a first embodiment of a footwear according to the invention with ventilation device in a side view, with the footwear in basic position, <Tb> FIG. 2 <SEP> is a side view of the footwear according to FIG. 1 in the loaded state and raised heel is raised in, in a side view, <Tb> FIG. 3 <SEP> is a perspective view of the shoe sole according to FIGS. 1 and 2, before assembly and without an insole, <Tb> FIG. 3A <SEP> is a plan view of the insole according to FIGS. 1 and 2, <Tb> FIG. FIG. 4 is a perspective view of the shoe sole of FIG. 3 after assembly but without the insole. FIG. <Tb> FIG. 5 <SEP> is a section along the line V-V in FIG. 4, <Tb> FIG. 6 <SEP> is a perspective view of a force transmitting line unit, <Tb> FIG. 7 <SEP> is a perspective view of a one arm lever, <Tb> FIG. 8 <SEP> is a perspective view of a compression unit, <Tb> FIG. 9 <SEP> a perspective view of a steering roller with a block, <Tb> FIG. 10 <SEP> is a perspective view of a lid of an air duct, <Tb> FIG. 11 <SEP> is a perspective view of an air pump, <Tb> FIG. 12 <SEP> a side view of the compression unit, <Tb> FIG. 13 <SEP> is a view of the compression unit, in the direction of the arrow XIII in FIG. 12, <Tb> FIG. 14 <SEP> is a side view of a split housing of the compression unit, <Tb> FIG. 15 <SEP> a side view of a second inventive footwear with ventilation device, in basic position, <Tb> FIG. 16 <SEP> is a side view of the shoe sole of FIG. 15, <Tb> FIG. 17 <SEP> is a perspective view of details of the solution according to FIG. 15, without insole, <Tb> FIG. 18 <SEP> is a view of further details of the solution according to FIG. 15, without insole, <Tb> FIG. 19 <SEP> is a longitudinal section of the shoe sole in the unloaded state, wherein the sectional profile can be seen with reference to the line IXX-IXX in FIG. 18, <Tb> FIG. 20 <SEP> the shoe sole according to FIG. 19 in the loaded or compressed state.

The same or similar details in the figures have been designated by the same reference numerals.

A first approach of the invention will be described in more detail below with reference to FIGS. 1 to 14.

1 and 2 show an inventively manufactured footwear 10, here in the form of a male shoe, with a shoe sole 12 and a top 14, which is fixed along the circumference of the shoe sole 12 in per se known. A foot of a shoe wearer is indicated in Fig. 1 with L. The shoe sole 10 is separated from the upper part 14 by an insole 16 on which the foot L is supported. The insole 16 is provided with a perforation 18 in the root area of the toes for the planned ventilation function, whose ventilation openings are designated 48 (FIG. 3A). The insole 16 has at least one continuous inlet opening 20 which in the footwear 10 provides a connection for the air under the inner bale (groin bend) and is positioned directly in front of a heel spur line and directly above a suction valve 40 (shown only symbolically in FIG. 1). Through this inlet opening 20 through so the air is sucked from the footwell of the shoe 10 in the shoe sole 12.

According to Fig. 1, the inventive shoe sole 12 consists of a flexible sole portion 22 and a stiffer heel portion 24. The heel portion 24 is formed as a hollow body and is preferably provided with a central support rib 26 (Fig. 3). On the inner side of the sole portion 22 recesses or notches 28 are configured, through which the sole portion 22 is formed lighter and more flexible. The C-shaped cavity of the heel part 24 is designated 30, which serves here as an air chamber.

Fig. 4 shows that here in the air chamber 30, an air pump 32 is arranged, the U-shaped surrounds the support rib 26 of the heel part 24 flanking. The air pump 32 forms part of a mechanical ventilation device 34 according to the present invention, which is operated by the movement of the foot L during the walking movement in the footwear 10, which will be described in more detail below.

The air pump 32 has a suction nozzle 36 and a discharge nozzle 38. The suction nozzle 36 is connected to the inlet opening 20 of the insole 16 airtight. The discharge port 38 is connected to the vent openings 48 of the perforation 18 (FIG. 3A) of the insole 16 through the pressure valve 42 and at least one air channel 46 formed in the shoe sole 12 and tightly covered from above , which are formed in the stem area of the toes. A cover which closes the air duct 46 from above is designated 54 in FIGS. 4 and 10.

The suction valve 40 and also the pressure valve 42 are each prefabricated as a complete one-way valve without backflow, and in each case a receptacle 50 and 52 of the shoe sole 12 installed and in position, for example. positively locked or glued. The air pump 32 is preferably made of rubber, with a bellows-type housing, as a flexible diaphragm pump. The air pump 32 is provided with a rigid cover plate 56 (FIG. 4).

The interior design of the shoe sole 12 for the installation of parts which have never been used in the shoe industry before, have been designed completely different from previous forms (Fig. 3). The intake and storage of the amount of air to the ventilation flow and the mechanical compression of the air pump 32 to provide an overpressure therein, in this case essentially by the, formed in the heel part 24 (shoe heel) air chamber 30 and the air pump 32 disposed therein dissolved.

Before the manufacture of shoes, first of all the ventilation device 34 according to the invention is produced by a packaging, i. by incorporating the prefabricated elements according to the invention into the prefabricated shoe sole 12.

As a first step in this process, the air pump 32 is installed airtight in the shoe sole 12. A bottom of the air pump 32 is e.g. attached by gluing to a bottom plate of the air chamber 30. The air pump 32 is then inserted from above and its two front connecting elements are connected to female members 58 of the heel piece 24, e.g. positive locking, locked.

During an adaptation of the assembly of the shoe sole 12 of the conventional manufacturing technology in the footwear industry, the next steps, the suction valves 40 and pressure valves 42 are installed according to the left and right feet (Fig. 4). These valves are here prefabricated units placed in corresponding recesses, e.g. in the receptacles 50 and 52 of the shoe sole 12 are received. In the receptacles 50 and 52, the suction valves 40 and pressure valves 42 are attached, e.g. by gluing. The pressure valves 42 (exhaust valves) and suction valves 40 (inlet valves) are in this case designed as one-way diaphragm valves, which ensure a reliable opening and closing function even at low pressure or low vacuum. As already mentioned, the suction valve 40 is arranged directly under the inlet opening 20 of the insole 16 and allows only an air inflow, so that no backflow is possible. Similarly, the pressure valve 42 allows only one air outlet.

The pressure valve 42 and an associated discharge nozzle 38 connects the air duct 46 via the distributed below the toe distribution channel 46A with the ventilation openings 48 of the perforation 18 (see FIGS. 3A and 4). To ensure that the air flow does not lose flow rate and velocity, the air duct 46 is hermetically sealed from the environment by a cover 54 (Figure 4).

In a recess 64 of the support rib 26 of the heel part 24 (Figure 3), e.g. by gluing a split housing 68 of a compression unit 34 of the inventive ventilation device 34 attached (Fig. 8). In this housing 68, a rotation axis 70 is rotatably mounted, which is provided on both sides with a respective rotatable eccentric disk 72 (Fig. 8, 12 - 14). Along the outer edge of the two eccentric discs 72 are each provided with a lateral squeegee 74, which a rigid cover plate 56th

The air pump in the sense of compression load downward / press (Fig. 4). At outer end faces of the eccentric discs 72 a concentric cord guide 76 is formed, which ends in cord-fixing receptacles 76 (FIG. 12).

The ventilation device 34 according to the invention further comprises a force-transmitting line unit 80 (Figure 6), which in this case consists of a cylinder 82 and two flexible cords 84 arranged at a predetermined distance from each other (Figure 6). The cords 84 are made of high strength materials, e.g. made of plastic cable. The one end of the cords 84 is fixed to the common cylinder 82, the other end is provided with a fixing rotatable bearing 86. The bearings 86 are in the receptacles 78 of the eccentric discs 72, e.g. secured by gluing (Figures 6 and 13).

In FIGS. 4 and 5 it can be seen that the force-transmitting cords 84 of the line unit 80 are guided via a deflection roller 88, which is freely rotatably mounted in a block 90 (FIG. 9). The bracket 90 is preferably secured in the shoe sole 12 by gluing.

A hook-shaped end 96 of a one-armed lever 94 is pivotably connected to the cylinder 82 of the force-transmitting line unit 80 (FIGS. 9 and 10). The other end 98 of the one-armed lever 94 is here provided with a vulcanized rubber coating and is fixed on a splice 100 to the shoe sole 12 (FIG. 3). The one-armed lever 94 is received by a recess 102 of the shoe sole 12, which preferably also allows a certain vertical movement of the lever 94.

From the inventive ventilation device 34 large amount of ventilation air is flowed in a walking movement in the footwear 10. This leads to unique, new ventilation properties and excellent wearing comfort. This real dynamic ventilation in the footwell of the shoe 10 is achieved, the used air from the footwell at the top of the upper part 14 can flow freely.

By the application of mechanical energy, which occurs in the walking motion due to the human foot and through which the shoe sole 12 is bent, which "rolls on the road surface", a new mechanical shoe ventilation technology is created according to the invention, which achieved an improved quality over the prior art. Due to the loading force caused by the body weight, a flexible sole bending deformation is triggered during the walking movement, by means of which and with which the mechanical ventilation device 34 causes a volume reduction (compression) and an air overpressure in the air pump 32. This positive air pressure is effective for actuating the shoe ventilation in the context of the invention.

Specific elements of the physiology of natural human walking motion are from the viewpoint of the invention, the load energy of the body weight, the effects during the walking movement and the step length and also the walking per unit time.

Depending on how one wears the footwear 10 and repeats the steps while walking, there are the characteristics of the distance traveled and the dismantling of the step process in partial movement elements. The phases of the steps are typically analyzable as a cyclic transition phase between the static and dynamic states. The initial phase is the departure from a standing position, the use of energy for the start, which is the first element of process progress.

While the tread-foot lifted off with the footwear 10 and after a normal stride length is placed back on the floor surface, reach the footwear 10 and its units or elements - because of their tendency to back and the energy acting - their unloaded state in the basic position. At the same time, the feature of the invention serving a new function is as follows:

During the walking movement of a person (e.g., man) wearing the footwear 10 of the present invention and having the treadle foot in the air while walking, the kinetic energy of the "supporting" or load bearing foot provides the ventilation effect. During the path of the tread foot in the air, the shoe sole 12 is "rolled" on the support foot in accordance with the dynamic tracking of walking on the floor surface, i. deformed. In this phase, the effects of the full body weight energy (weight load P) are utilized for realizing the ventilation function of the invention.

1 and 2 it can be seen that the shoe sole 12 after installation of the described elements and during the support phase dynamically follows the support foot and the displacement of the body center of gravity is used. During the movement of the tread foot in the air and before landing on the floor surface, there is a support foot operation in the process, which creates a "phase shift" at each step. In repetition of this process, the support foot takes over the phase path of the treadle foot and the treadle foot the phase path of the support foot. During the support phase, the elements of the invention are activated and thus the ventilating air flow according to the invention is produced as follows:

At the start of walking the rearmost point A of the heel part 24 is lifted from the road surface. Consequently, the body weight is displaced on the support foot, i.e., on the glued end 98 of the one-armed lever 94 (point C indicated in Fig. 5). Since the front end 98 of the one-armed lever 94 is fixed, and the hook-shaped rear end 96 of the one-armed lever 94 remains immobile because of concentrating in the point C weight load P (load) until the cessation of the load.

During this phase, connected to the hooked end 96 of the one-armed lever 94 roller 82 of the power transmitting unit scissors 80 moves obliquely and relatively away from the guide roller 88. By this displacement is achieved that the other ends of the cords 84, the corresponding eccentric discs 72 tighten so that they are rotated about 90 ° in the opposite direction of the clockwise about the axis of rotation 70. As a result, the squeeze vanes 74 of the eccentric disks 72 depress the rigid cover plate 56 of the air pump 32, thereby reducing the volume, i. E. a compression in the interior of the air pump 32 is generated. This volume reduction in the air-tightly mounted air pump 32 thus causes an overpressure, so that the air flow is conveyed through the pressure support 38 and the pressure valve 42 in the air duct 46 and via the distribution channel 46A and then through the ventilation openings 48 in the spaces between the toes.

The volume of air supplied is about 40 cm <3>, e.g. in the case of an average man (EU shoe size 42) according to tests carried out. From a quantity of air compressed during a step, about 20 cm 3 is conveyed to the toe area in the manner described. This phase of walking is over when the support foot is raised. Then the role of this foot is taken over by the other foot. These process steps are repeated cyclically.

Of course, this present invention is also suitable for actuating the ventilation device 34 according to the invention, even without walking, that is, only by raising the heel portion and downward pressure of the leg muscle, and even in a sitting position of the footwear wearer. The point A of the heel 24 (heel) is raised to point A, the height of which is indicated by M (Figures 2 and 5).

After completing the weight load P, the elastically deformable air pump 32 is able to perform its own expansion / expansion because of its modulus of elasticity. to return to a basic position. Their rigid cover plate 56 and also the pressing vanes 74 of the compression unit 66 come into an uppermost position (FIG. 1). During the path of the tread-foot in the air, the expanding air pump 32 takes up its original volume, again being filled with fresh air through the inlet opening 20, the suction nozzle 36 and the suction valve 40.

During the above-described use of footwear 10 (eg when the user was walking) at ordinary stride lengths, for one hour and over a distance of 5 km, in the experiments performed the foot space of the footwear 10 was of a ventilation air volume of about 200 dm3 flows through. Thus, a surprisingly dynamic and effective ventilation of the shoe 10 is achieved.

In Fig. 5, the support foot on the road surface in the static state is denoted by thick line. In this state, the ventilation device 34 is in an unloaded basic position in which the air pump 32 is filled with air. It can be seen in Fig. 5 in longitudinal section of the heel part 24 that in this solution, the air pump 32 is housed in the cavity of the air chamber 30 of the heel part 24 (the pump is not shown here). The front corner of the cavity (air chamber) 30 is designated B.

As can be seen in Fig. 5, the axis of rotation 70 of the co-rotating eccentric discs 72 is now in a 6 o'clock position. In this state, the presser vanes 74 of the eccentric disks 72 are in their upper basic position.

In the basic position, the weight load P is distributed uniformly over the heel part 24 and the portion 108 of the sole part 22. The rearmost point A of the heel part 24 rests on the road surface. The one-armed lever 94 and its hook-shaped end 96 are now in the starting position and remain in this position.

During walking one lifts from a starting position by lifting the tread-foot and at the same time the support foot is loaded by the full weight load P from the body weight, whereby a "rolling" of the shoe sole 12 begins (ie, the sole parts are elastically bent in section 108 and in point C) and both feet start to move.

The proposed foot and shoe ventilation according to this invention is achieved by the overall effect of these rolling forces and the elements of the particular ventilation device 34. The phase begins with the raising of the rearmost point A of the heel part 24 to the point A, as indicated by M (Figure 5).

To ensure a minimum ventilation air flow according to the invention is already sufficient to raise the heel part 24 by such a section in which the vulcanized end 98 of the one-armed lever 94, a sufficient clamping force as weight load P exists. The force due to the weight load P, e.g. from the weight of an adult male by 70 kg, then acts as a clamping force in the rolling phase until the load on the supporting foot is removed (i.e., until the support foot is raised and the other foot is loaded).

For actuating the ventilation device 34 according to the invention, the vulcanized end 98 of the one-armed lever 94 remains stationary because of the clamping force originating from the weight load P. It follows that also the hook-shaped end 96 of the one-armed lever 94 hinged to the force-transmitting line unit 80 remains stationary. As a result of the resulting from the raising of the heel part 24 from point A to point A deformation resulting load is passed through the line unit 80 on the eccentric discs 72. In this case, the guide roller 88 moves - together with the heel part 24 - upwards in an upper position 88th Consequently, the eccentric discs 72 are rotated counterclockwise about the common axis of rotation 70. The axis of rotation 70 of the eccentric discs 72 is now in a 3 o'clock position (see FIG. 5).

As the point A of the heel part 24 moves in the direction of the upper point position A, it returns a height M (Figure 2), at the same time reducing the distance between the point B and the axis of rotation 88. As a result, the squeeze vanes 74 are brought to the lower position, whereby the air pump 32 - by its rigid cover plate 56 - pressed down by means of the two squeeze wings 74, i. compressed, is.

The physical clamping effect when walking ends when the line of action of the one-armed lever 94 in the same position retaining clamping force leaves the arcuate portion 108 of the shoe sole 12 (Fig. 5). Subsequently, this foot is lifted with the footwear 10 of the road surface and takes over the other foot, the support foot function. In this case, the integrated air pump 32 expands by its own elastic resilience, with its rigid cover plate 56 raises in its upper basic position. Meanwhile, the air pump 32 sucks fresh air from the ankle area of the foot space through the inlet port 20 and the suction valve 40.

After the, from the walking movement given deformation load, the «curvature» of the shoe sole 12, stops, during their movement in the air, this returns to its original position. At the same time, the elements or units of the ventilation device 34 are returned to their normal position. At each subsequent step of walking, the movements of both feet are cyclically repeated as described above.

The inventive ventilation device 34 allows in the footwell so an intense and cyclic air circulation through which the footwell remains dry and the moisture and air through the cyclic compression and expansion of the air pump 32 is removed from the footwell. As a result, the shoe-wearing comfort is improved in a surprising way.

In the proposed shoe ventilation according to a second embodiment of the invention, the ventilation is actuated in a special way by a deliberately planned deformation. This solution will be explained below with reference to FIGS. 15 to 20.

During the experiments carried out we have recognized that the footwear wearer loads the shoes during walking usually by the full weight as weight load P. This weight load P is proportional to the body weight. Thus, this feature is also suitable to provide a special topographical construction and structure of the material composition for the shoe sole 12. As a result, a predetermined overpressure can be brought about cyclically in the shoe sole 12, as a result of which an aeration flow in the footwell circulates effectively.

In this solution according to the invention cavities are provided in the shoe sole 12 topographically regard as air chamber with predetermined volume from each other and airtight sealed from the environment. These cavities or air chambers are designed so that they are elastically deformable proportionally in a predetermined, proportional extent under the weight load P, whereby an overpressure of the air in the cavities or air chambers is produced.

The "mechanism" of walking consists of step-by-step virtually infinitely repeatable process series, which can be assigned to different characteristics. The intentionally used elastic deformation and the positive air pressure in the shoe sole 12 for establishing the ventilation flow requires that this be adjusted after the elastic deformation and the shoe sole 12 is returned to its original state.

In the solution according to the invention according to FIGS. 15 and 18, a unique solution is achieved by the special topographical design, on the other hand by the chemical formulation of the materials used for the shoe sole 12 of the footwear 10. In the cyclic aeration flow method, the ventilation air in the shoe sole 12 is regulated (as explained above) using one-way suction valves 40 and one-way pressure valves 42 which also operate at low pressure or vacuum, i. they open or close (Fig. 15).

This new construction according to the second inventive solution differs from the first embodiment by the shoe sole 12 of the shoe 10, which has a multi-layered design.

It is known that when walking, the outer, so-called "running layer" in the surface contact area is exposed to considerable wear. Therefore, in this embodiment, a separate running layer 110 is used, which is made of rubber, as usual in the footwear industry. The central layer of the shoe sole 12 is formed as a special intermediate layer 112, which in this case is made of polyurethane. The third uppermost layer of the shoe sole 12 is formed by the insole 16.

As regards the chemical composition of the intermediate layer 112, the following is added:

According to the invention, the average weight of an average shoe wearer is considered as a "basic setting". An average man usually has an EU shoe size 42 and a weight of 70 to 75 kilograms. In this "default" polyurethane is used for the intermediate layer 112. To formulate the polyurethane used for the intermediate layer 112, various components and additives, e.g. Crosslinking addition, filler, binder addition in accordance with the required properties, after tests added.

In an adapted to a greater weight footwear 10 is for the formulation of the polyurethane used, the intermediate layer 112 preferably in weight percent smaller amount of a known crosslinking surcharge, but a higher proportion of known filler material and color «(eg to the black color: carbon) and added by the process-shortening binder addition.

For the foamability of the polyurethane, i. for liquid volume growth of the material more than five times, the crosslinking penalty is responsible. The crosslinking actually results from microporosity within the material, which in practice means the formation of small air pockets in the polyurethane. This actually determines the compressibility or elastic recovery properties of the original volume of a polyurethane element.

Thus, it will be apparent to one of ordinary skill in the art that if the crosslinking penalty is reduced or if the polyurethane is optionally solidified or partially loaded with other additives, this will result in smaller volume reduction, i. Compressibility allows for the same load P. Thus, only a shoe carrier of higher weight would be able to produce the novel ventilation air flow in the required mass.

It should be emphasized that this property, in addition to the choice of the above formulation, by the topography of the shoe sole 12, i. by the use of mechanically closed, separate, load bearing and recoverable air chambers, i. from the primary air chamber 30, and the secondary air chambers 114 formed as cylinders and / or the tertiary air chambers 116 formed as air spring can be "assisted" and regulated (FIGS. 15 and 18). As a result, the ventilation function is made even more complete in footwear 10 according to the invention.

For lower body weights but the above recipe of the intermediate layer 112 of the shoe sole 12 in comparison to the "default settings", just in the opposite sense to be changed. However, having regard to the above disclosure, there is no need for further teaching by one of ordinary skill in the art.

An important aspect in selecting the chemical composition and physical parameters of the intermediate layer 112 is that the respective body weight causes a vertical deformation, i. E. a compression of e.g. 5-12 mm in the shoe sole 12 to be generated, which allows a sufficient reduction (compression) of the air space of the air pump 32. About 50% of the air stored in the air chambers is pressed out by the overpressure and thus the ventilation air flow in the inventive footwear 10 is generated. The volume changes in proportion to the shoe size and is e.g. about 45 to 52 cm <3>.

In Fig. 16 it can be seen that the shoe sole 12 as a third inner layer has an insole 16, which - as mentioned above - the shoe sole 12 from the upper part 14 of the shoe 10 (not shown here) separates and on which the foot is supported in its basic division. FIGS. 15 and 16 illustrate the ventilation openings 48 of the perforation 18 at the base of the toes and also the inlet opening 20 on the sole-vault, the latter being connected to a suction nozzle 36 of the suction valve 40.

In the shoe sole 12, as in the first embodiment, a distribution channel 46A is provided under the base of the toes to ensure that the ventilation flow is distributed between the toes throughout. The one end of the distribution channel 46A is connected to an air passage 46 and the other end is connected to a discharge port 38 of the air pump 32. The air duct 46 is hermetically sealed at the top with a cover 54 in order to eliminate the air losses. The one-way suction valve 40 is respectively disposed on the inside of the shoe sole 12 so that it is in communication with the inlet opening 20 of the insole 16.

According to the invention, the shoe sole 12 contains at least one primary air chamber 30, which is formed in the intermediate layer 112 of the shoe sole 12. In this embodiment, there is a single primary air chamber 30 formed in the intermediate layer 112 from the heel area to the midportion as a female recess and dimensioned to be capable of receiving a significant amount of air. An S-shaped front interface of the primary air chamber 30 is designated 118 (Figure 18).

In this second embodiment additionally formed as a cylinder secondary air chamber 114 are provided, which are preferably in the cavity of the primary air chamber 30, but of which airtight separated, are formed. These secondary air chambers 114 are also important components of this construction, since by applying pressure to the shoe sole 12, an overpressure of the air trapped in the cylinders is achieved, which assists in the elastic recovery of the shoe sole 12. On the other hand, at contact surfaces of the cylinders prior to their placement, e.g. by gluing at least one gap of small width (not shown) for predetermined outflow of air from the cylinder into the air chamber 30 are formed or provided.

Each cylinder as a secondary air chamber 114 plays a role in that the weight of the shoe wearer corresponds in proportional mass of shoe ventilation. It is understood that if each cylinder is hermetically sealed as the secondary air chamber 114, they will exert the greatest reaction forces against the maximum compressibility / loading force, but if these cylinders are used in a sufficient number of columns, as explained above, they may Reaction forces are reduced to the desired / predetermined extent - according to the weight of the respective shoe wearer.

By deliberately closing or opening the mentioned column (or "tapping off" the cylinder through other openings) of the cylinder as a secondary air chamber 114, according to the invention, the production of a footwear 10 is further promoted or simplified. That is, footwear 10 adapted to the weight corresponding to the respective shoe size can be easily manufactured.

Thus, the present invention introduces a new feature in footwear practice, in addition to the shoe size and shoe width and the body weight of the shoe wearer is considered as a new choice criterion. This makes it possible for users not only to choose or order suitable footwear based on the size and width of their feet but also on their body weight.

Different needs for footwear 10, e.g. EU footwear size 42 when footwear 10 is worn over a long period by a 100kg adult, or for a shorter period by a 40kg teenager.

According to the invention, it is expedient for the shoe sole 12 to be provided with tertiary air chambers 116 as additional air springs (FIGS. 18 and 19). These are preferably formed as blind holes, along an outer wall of the intermediate layer 112 and sealed airtight from above. Due to the weight load P (compression force) of the shoe sole 12 and the caged air amount of air springs is set as tertiary air chambers 116 under pressure, which significantly supports after adjustment of the load elastic recovery of the shoe sole 12 in its original state.

The prefabricated completed shoe sole 12 (after installation of the internal components of the ventilation device 34 according to the invention) as the main component of the footwear 10 is then connected to the upper part 14, e.g. by gluing, thereby creating a new service, namely an offer confirmed by measurable parameters, for footwear 10 ventilated by predetermined dynamic airflow.

When the finished footwear 10 are tightened, they are evenly loaded when getting up by the weight load P, so that the two shoe soles 12 are easily deformed by the burden. At the start of walking, the treadle foot is raised with the entire weight load P transferred to the support foot. As a result, therefore, the primary air chamber 30, the secondary air chambers 114 and the tertiary air chambers 116 are elastically compressed by the weight load P. This weight load P increases the air pressure in the primary air chamber 30 and also in the secondary air chambers 114, as well as in the tertiary air chambers 116. This overpressure in the primary air chamber 30 opens the one-way pressure valve 42 which controls the flow of air from the primary air chamber 30 into the primary air chamber 30 Air duct 46 leaves (FIGS. 15-18). From the air duct 46, the air flow is passed into the distribution channel 46A and through the ventilation openings 48 of the perforation 18 of the insole 16 into the foot space between the toes, wherein the air can then flow to the outside at the edge of the upper part 14 to the outside.

However, the placement of the tread on the ground is associated with considerable energy, which amounts to 50% of the body weight during normal walking. In the case of running or jogging, when the two feet are longer in the air due to the fast foot lever, this energy is even around 110 to 120% of the body weight, according to experiments.

By the construction of the present invention, the above-mentioned impact energy is largely absorbed by the shoe sole 12, which also provides a very valuable damping against the otherwise harmful impact effects of the joints.

The construction of the shoe sole 12 allows a vertical elastic deformation or compression of the primary air chamber 30, the sealed secondary air chambers 114 and the tertiary air chambers 116 - deliberately planned - of about 5 to 12 mm on impact of the foot on the foot Ground. The amount of air stored in the air chamber 30 is e.g. about 45 to 52 cm <3> (with the amount of air having a volume that changes proportionally with shoe size). About 50% of the amount of air is pressed out by the overpressure and thus generates the above-mentioned ventilation air flow.

Of course, the volume of the air chamber 30 increases when the weight load P is adjusted. In this phase, fresh air is sucked into the air chamber 30 for air exchange by the disposable suction valve 40 from the ball area of the foot space.

A major advantage of the second solution according to the invention is that e.g. the effectiveness of the ventilation air flow is increased by 50% according to experiments carried out by the application of the construction of the shoe sole 12.

In Fig. 19, the air chambers that are compressible by the weight loading P, i. the air chamber 30, 114 and 116, to see whose air spaces form the primary air chamber 30, the secondary air chambers 114 and the tertiary air chambers 116. The first volume of air forms the undistributed primary air chamber 30, which extends from the heel to the front line of the leg muscle and is bounded at the front by the S-shaped boundary surface 118 (Figure 18). The second closed air volume is determined here by six cylinders as secondary air chambers 114. The third closed air volume is determined by the nine tertiary air chambers 116 as air spring.

The formation of the secondary air chamber 114 and the tertiary air chambers 116 has two functions:

In use, in all air chambers 30, 114, 116, an increased air pressure prevails due to the weight load P already described. As a result, the one-way suction valve 40 closes according to the pressure rise in the air chamber 30 and at the same time opens the one-way pressure valve 42. At this stage, the air flow from the air chamber 30 through the air duct 46 and the distribution channel 46A and through the ventilation openings 48 of the perforation 18 of the insole 16 led to the foot space between the toes.

The resistance to compression of the closed cylinder 114 and the air spring 116 when compressed increases steadily and also the pressure in the closed chambers increases. These cylinders 114, along with the air springs 116, guarantee that upon adjustment of the compressive load P, the elements elastically expand to the original volume, i. reset, and at the same time an extraction of fresh air from the ball area is carried out in the air chamber 30 by this expansion.

If necessary, since the intermediate layer 112 is turned upside down by 180 ° when installed compared with the previously opened up state, and installed in the shoe sole 12 in such a rotated posture after installation of the wear resistant running layer 110, durability of the footwear becomes 10 significantly increased. The flat adaptation of the surfaces to be glued together of the layers 110 and 112 also becomes more advantageous, as a result of which the achievement of the set tasks is effectively supported.

The conventional shoe soles were made on the load which is usually expected in relation to the shoe sizes usually. For example, for an adult man with EU shoe size 42 and a weight 75 kg means. As a result, only a slight ventilation in the shoe was possible, but a new kind of sizing of the footwear virtually impossible.

As a result of the inventive development, a new design and manufacturing system for the shoe industry and the shoe trade is introduced, which also takes into account the body weight of the respective shoe wearer. On the other hand, the footwear comfort and the service life can be significantly increased.

Thus, the new possibility of the present invention is that, for the first time in the world, the purchaser, besides the foot size, e.g. No. 42, as well as the foot width (A, B, or C) Shoes can also choose or order the body weight. Incidentally, the body weight is also taken into account for the effective actuation of the ventilating device 34 of the footwear 10 according to the invention.

Fig. 19 shows the initial state of the shoe sole 12, which also corresponds to the restored end position of the shoe sole 12. When lifting the tread foot, the weight load P is set and at the same time as a result of the material structure and the topographical design of the inventive shoe sole 12 from the elastically compressed state in the expansion process (regression) starts. As a result, the increase in volume achieves the suction effect described above, the end point of which can be marked with the uncompressed original state (FIG. 19).

With step changes in the course of walking, until the tread foot in the air makes its way, the support foot gives weight load P on the shoe sole 12 (Figure 20). In this process element, the total weight load P is substantially carried by the air chambers 30, 114 and 116. Optionally, this may be increased to increase the additional power of a cylinder 114 for sizing pre-formed weight groups (in synchrony with body weight gain, e.g., in the case of a 90 kg adult) or (if the user has less than 75 kg body weight). In the latter case, the air chamber is opened by at least one cylinder 114 through a slot, so that its air chamber is connected through the slot with the primary air chamber 30. That is, the amount of air in the slotted cylinder 114 is added to the air amount of the primary air chamber 30.

In essence, the air chamber 30 is the location where the air is exchanged at each step. This is the actual mechanism, i. the ventilation device 34, which performs the dynamic ventilation function in footwear 10 - as explained above - mechanically and reliably.

Depending on the weight of the respective buyer and for an effective ventilation effect, a number adapted to the EU shoe size and cylinder 114 exposed by a slot can be provided or the number of closed cylinders 114 can be increased. The air springs 116 may be used as blind holes, e.g. before the layers 110 and 112 stick together, preferably by milling.

In the two illustrated embodiments of the invention, the sequence of operations is as follows:

The first inventive technology (see FIGS. 1 to 15):

[0114] Phase 1: The air pump 32 built into the air chamber 30 of the heel part 24 is pushed down by the raised heel part 24, the counteracting one-armed lever 94, the power transmission line unit 80 and the compression unit 66, thereby becoming air space the air pump 32, an overpressure is generated; <tb> • <SEP> Phase 2: In a next phase of walking, the shoe sole 12 aligns, i. as a result, fresh air is sucked from the bale area through the suction valve 40 into the air pump 32; Phase 3: Walking, the one-armed lever 94 attempts to counteract the rising heel portion 24. From the air pump 32 is simultaneously a large amount of ventilation air through the pressure valve 42, the air duct 46, the distribution channel 46A and the vents 48 of the perforation 18 in the footwell, i. promoted to the base of the toes.

During walking, in the footwear 10 according to the invention, a large amount of air flows dynamically when lifting the heel and into the foot space, whereby a new, unique and high-performance ventilation quality of the footwear 10 is achieved. The "used" air flows from the footwell at the upper edge of the upper part 14 into the open air.

These designs represent a significant increase in efficiency in the technical parameters, which has been confirmed by experiments, compared to the prior art. So it has been possible to create a ventilation of the shoe 10 of exceptionally high quality and to increase the wearing comfort of the shoe 10 significantly.

The second technology according to the invention (see FIGS. 15 to 20):

[0117] Phase 1: The air of the elastic air chamber 30 of the shoe sole 12 is elastically compressed during walking by the weight load P, whereby an air pressure arises in the air chamber 30; Phase 2: After discharge, the flexible air chamber 30 expands (expanded) while fresh air from the ankle area is drawn into the air chamber 30 through the suction valve 40 and the inlet port 20; Phase 3: During walking, the pressure of pressure 42 is opened by the excess air pressure established by the weight load P in the air chamber 30, and the ventilation air from the air chamber 30 is passed through the air passage 46, the distribution channel 46A, and the vents 48 of the perforation 18 of the insole 16 in the footwell of the footwear 10, ie, passed to the base of the toes; Phase 4: Due to the positive air pressure in the cylinders as secondary air chambers 114 and / or in the air springs as tertiary air chambers 116, the elastic return (alignment) of the curved shoe sole 12 is further supported.

The essence of the second solution according to the invention is further seen in that at least a part of the shoe sole 12, preferably its intermediate layer 112, has such a chemical material composition, elasticity and / or geometric shape (topography), which depend on the respective pressing force or force the weight load P as a function of the body weight of the footwear wearer is determined in such a way that a predetermined ventilation air flow is generated in the foot space of the footwear 10 during the walking by the elastic compression of the shoe sole 12, preferably its intermediate layer 112.

As already mentioned above, the inventive mechanical ventilation device 34 in addition to the primary air chamber 30 is preferably also provided with secondary air chambers, preferably cylinders 114 and / or tertiary air chambers, preferably air springs 116, preferably in the intermediate layer 112, which originally from each other are physically airtight. One or more of the secondary air chambers 114 may optionally be connected to the primary air chamber 30 through a gap, as discussed above.

Preferably, the number and volume of the secondary and / or tertiary air chambers 114 and 116 and the density and elasticity of the material of the shoe sole 12, preferably the intermediate layer 112, depending on the respective weight load P of the shoe wearer is selected or determined.

Optionally, in the air chamber 30, a deodorant can be used.

The aforementioned measures of the present invention achieve superior ventilation and wearing comfort of footwear 10 over the prior art, representing significant technical and economic progress and surplus for shoe manufacturers and users.

LIST OF REFERENCE NUMBERS

[0123] <Tb> 10 <September> Footwear <Tb> 12 <September> shoe sole <Tb> 14 <September> shell <Tb> 16 <September> insole <Tb> 18 <September> perforation <Tb> 20 <September> inlet opening <Tb> 22 <September> sole part <Tb> 24 <September> heel <Tb> 26 <September> support rib <Tb> 28 <September> notch <tb> 30 <SEP> air chamber / cavity in 24th <Tb> 32 <September> Air Pump <Tb> 34 <September> aeration device <Tb> 36 <September> suction <Tb> 38 <September> pressure connection <Tb> 40 <September> disposable suction valve <Tb> 42 <September> disposable pressure valve <Tb> 46 <September> air duct <Tb> 46A <September> Distribution Channel <Tb> 48 <September> vent <Tb> 50 <September> Recording <Tb> 52 <September> Recording <Tb> 54 <September> Lid <tb> 56 <SEP> rigid cover plate <Tb> <September> <Tb> 60 <September> Recording <Tb> 62 <September> Recording <Tb> 64 <September> recess <Tb> 66 <September> compression unit <Tb> 68 <September> Housing <Tb> 70 <September> axis of rotation <Tb> 72 <September> eccentric <Tb> 74 <September> press blade <Tb> 76 <September> line guide <Tb> 78 <September> Recording <tb> 80 <SEP> power transmission line unit <Tb> 82 <September> roller <Tb> 84 <September> string <Tb> 86 <September> Bearings <Tb> 88 <September> guide roller <Tb> 90 <September> Bock <Tb> 92 <September> Recording <tb> 94 <SEP> one-armed lever <tb> 96 <SEP> hook-shaped end of 94 <tb> 98 <SEP> other end of 94 <Tb> 100 <September> splice <Tb> 102 <September> depression <Tb> 104 <September> Sole vault <tb> 108 <SEP> arc section d of FIG. 22 <Tb> 110 <September> overlay <Tb> 112 <September> interlayer <tb> 114 <SEP> secondary air chamber <tb> 116 <SEP> tertiary air chamber <tb> 118 <SEP> Interface of 30 <Tb> <September> <tb> M <SEP> Height of A <tb> L <SEP> Foot in footwear <tb> A, A <SEP> rearmost point <tb> B, B <SEP> front point of 30 <tb> C <SEP> Point of attack of P <Tb> P <September> weight load

Claims (10)

1. footwear with a ventilation device having a shoe sole (12) and an associated, especially closed upper part (14), wherein the shoe sole (12) consists of a flexible sole member (22) and a rigid heel part (24) and is covered by an insole (16), and in that the shoe sole (12) is associated with a ventilation device (34) actuated when walking through the foot (L) of a footwear wearer, wherein at least one air chamber (30) of the ventilation device (34) in the Shoe sole (12) is formed, which with a, the air chamber (30) filled with air disposable suction valve (40) and one, the compressed air of the air chamber (30) as aeration air flow in a foot space of the footwear (10) through ventilation openings (48 ) of the insole (16) conveying disposable pressure valve (42) is provided, characterized in that the ventilation device (34) comprises an air pump (32) which is arranged in the air chamber (30), wherein a sow gstutzen (36) of the air pump (32) with the disposable suction valve (40) and a discharge nozzle (38) of the air pump (32) with the one-way pressure valve (42) is connected, and that the ventilation openings (48) of the insole (16 ) are formed in the stem area of the toes, and that the disposable suction valve (40), the air pump (32) is arranged refillable with fresh air from the ball area of the footwell, and that, when operated by the foot (L) of a shoe wearer actuated ventilation device (34) has a, preferably made of steel, one-armed lever (94) whose front end (98) to the shoe sole (12) is preferably secured in a Schuhnasenbereich, the rear end (96) but with the air pump (32) in one Actuator connection is. 2. Footwear according to claim 1, characterized in that for the actuation connection of the one-armed lever (94) with the air pump (32), the ventilation device (34) is provided with a force-transmitting line unit (80) and an associated compression unit (66) between the one-armed lever (94) and the air pump (32) are inserted, wherein the force transmitting line unit (80) preferably comprises a roller (82) and at least one load transmitting flexible cord (84) connected at one end to the roller (82), the roller (82) having a hooked end (96) of the one arm lever (94) is hinged; the other end of the cord (84) is connected to at least one rotatably mounted eccentric disc (72) of the compression unit (66) in such a sense that the eccentric disc (72) is rotatable by tightening the cord (84) and the at least one Eccentric disc (72) of the compression unit (80) with a, during rotation of the eccentric disc (72) through the cord (84) of the air pump (32) compressing / compressing presser blade (74) is provided. 3. Footwear according to claim 1 or 2, characterized in that the air chamber (30) in the heel part (24) is formed as a cavity having a support rib (26), preferably in a recess (64) of the support rib (26). the compression unit (66) is arranged. 4. Footwear according to one of claims 1 to 3, characterized in that the air pump (32) is designed as a flexible diaphragm pump with a rigid cover plate (54). 5. footwear with a ventilation device, which footwear (10) has a shoe sole (12) and an associated upper part (14), wherein the shoe sole (12) consists of a flexible sole member (22) and a rigid heel part (24) and is covered by an insole (16) and in that the shoe sole (12) is associated with the ventilation device (34) actuated by the foot (L) of a shoe wearer, at least one air chamber (30) comprising the ventilation device (34) at least one Air chamber (30) which is formed in the shoe sole (12), which with a, the air chamber (30) filled with air disposable suction valve (40) and one, the compressed air of the air chamber (30) as aeration air flow into the footwell of the footwear (10) by means of ventilation openings (48) of the insole (16) conveying disposable pressure valve (42) is provided, characterized in that the flexible shoe sole (12) at least partially made of a material, in particular e is made of plastic whose density and elasticity as a function of a weight load (P) according to the body weight of the respective shoe wearer is determined so that the volume change of the air chamber (30) by a compression of the shoe sole (12) for producing a predetermined value of a cooling air flow is held; and in that the ventilation openings (48) of the ventilation device (34) actuated by the movement of the foot (L) during walking are provided in the insole (16) at the root area of the toes, and in that the one-way suction valve (40) is the primary air chamber (30) is arranged refillable with air from the ball area of the footwear (10). 6. Footwear according to claim 5, characterized in that the flexible shoe sole (12) is multi-layered, wherein at least a part thereof, preferably its intermediate layer (112), made of a plastic, in particular made of polyurethane, or the shoe sole (12 ) has a multi-layer structure, which consists of an outer running layer (110), preferably made of rubber, an intermediate layer (112) made of plastic, in particular polyurethane, and an inner insole (16). 7. Footwear according to claim 5 or 6, characterized in that the ventilation device (34) in addition to the primary air chamber (30) and additional air chambers, preferably designed as a cylinder secondary air chambers (114), which separated from the primary air chamber (30) airtight are; said secondary air chamber (114) being formed in the shoe sole (12), preferably in the intermediate layer (112), wherein at least one of the secondary air chambers (114) is preferably connected by slots to the air space of the primary air chamber (30). 8. Footwear according to claim 7, characterized in that the ventilation device (34) is provided with additional, of the primary air chambers (30) airtight tertiary air chambers (116), preferably air springs, which in the shoe sole (12), preferably in the intermediate layer (112) are formed. 9. Footwear according to claim 7 or 8, characterized in that the volume of the primary air chamber (30), as well as the volume and the number of secondary and / or tertiary air chambers (114 or 116), as well as the material density and flexibility of the shoe sole ( 12), preferably the intermediate layer (112), depending on the weight load (P) is determined according to the body weight of the respective shoe wearer. 10. Footwear according to one of claims 1 to 9, characterized in that in the air chamber (30) a deodorant filling is arranged.