ITTV20090006A1 - DEVICE FOR INTERNAL SCREEN VENTILATION - Google Patents

Abstract

The present invention relates to a device (20) for internal ventilation of a shoe (10) comprising a pumping unit (40) suitable for sucking in air from the outside towards the inside the shoe (10); an input chamber (70) suitable for introducing the air sucked in by the pumping unit (40) inside the shoe (10); and a connecting channel (50) suitable for conveying the air sucked in by the pumping unit (40) towards the input chamber (70). The device 20 is also characterized in that it comprises hygroscopic means (36) suitable for reducing the degree of relative humidity of the air introduced inside the shoe (10). The invention also relates to a shoe (10) containing such a device (20).

Description

“Device for internal shoe ventilation”.

DESCRIPTION

The present invention relates to a device for internal ventilation of a shoe, in particular a device, which can be coupled to a sole, which allows the forced circulation of air inside a shoe.

Said invention also relates to a shoe containing a device for internal ventilation of a shoe.

Currently, synthetic materials are widely used in the production of sports and walking shoes. These materials have made it possible to increase productivity and reduce industrialization costs. They have also allowed the creation of footwear that can better conform to the anatomy of the foot and increase the comfort perceived by the user. Compared to natural materials, however, these synthetic materials are less breathable and consequently their use increases the problems associated with excessive and unwanted foot sweating. Components such as rubber soles, thermoformed insoles, water-repellent buttresses, in fact thermally insulate the foot from the external environment, almost completely preventing the exchange of heat between the inside and the outside of the shoe. Consequently, it is not possible to disperse the heat that, as known, is generated inside the shoe due to the movements made by the foot during walking or running.

This heat causes an increase in temperature which induces an increase in foot sweating and an increase in relative humidity inside the shoe. High temperature and relative humidity cause discomfort for the user, since inside the shoe there is no longer a healthy and hygienically clean and dry environment. This discomfort is amplified in the case of prolonged and particularly intense use of the shoe.

Currently, the market offers various devices and methods to promote air circulation inside a shoe. However, these devices, while widely appreciated, are not free from defects.

One of the proposed technical solutions consists in piercing the tread of a sole, interposing a breathable membrane between the tread and the insole or between the tread and the midsole. The membrane on the one hand ensures the waterproofing of the sole, on the other it allows excess moisture formed inside the shoe to escape through the holes made in the tread. The main disadvantage of this device is represented by the fact that the holes made in the tread, during the normal use of the shoe, can easily be blocked by substances present on the ground. Dirt, mud, dust, sand or similar components, in fact, can obstruct the holes, limiting or completely preventing communication between the inside of the shoe and the external environment. It should be noted that, by virtue of the small diameter of the holes themselves, it is difficult if not impossible for the user to free the holes from any external bodies. This operation, which can only be performed with the help of pointed bodies, could in fact damage the membrane. Another disadvantage is represented by the fact that the membrane, at the point where the sole of the foot flexes, with continued use, can deteriorate to the point of tearing. Consequently, the shoe is no longer waterproof and water can pass through the sole, wetting the user's foot.

Another proposed technical solution involves the use of a pumping device, positioned in a suitable seat obtained inside the sole. This device is able to suck in the hot and humid air present inside the shoe and expel it to the outside while maintaining an airy and conditioned internal environment. The pumping device is activated by the movement that the user's foot makes while walking or running. It consists of an aspiration chamber, located in the area of the sole of the foot, and a pumping chamber, located in the heel area, connected to each other by means of a duct. The air is sucked from inside the shoe through the suction chamber and through the duct is made to flow towards the pumping chamber which alternately sucks air from the duct and expels it to the outside. A first non-return valve is placed between the suction chamber and the pumping chamber; a second non-return valve is placed between the pumping chamber and the outside. These valves ensure that the air flow can only flow in one direction, from the inside to the outside of the shoe. A disadvantage of this device is represented by the fact that the ventilation effect is limited. By not introducing new air into the shoe, the foot continues to remain inside an environment characterized by high temperature and relative humidity.

A further proposed technical solution provides for the use of a pumping device comprising an intake chamber, located in the heel area, an inlet valve, an outlet valve, a duct and a plurality of grooves located in correspondence with the area. of the plant. The pumping chamber has a channel that connects it to the outside of the shoe. When the user walks or runs, the air sucked in from the outside is sent, through the duct and the grooves, to the inside of the shoe. The valves ensure that the air flow can only flow in one direction, from the outside to the inside of the shoe. In the case of rainy or humid days, however, it may happen that the air introduced into the shoe is characterized by a degree of relative humidity that is slightly lower or even higher than the degree of humidity present in the shoe. Consequently, the user derives only a marginal if not zero benefit from the introduction of air inside the shoe.

The object of the present invention is therefore to overcome the drawbacks of the known art.

In particular, a task of the present invention is to make available a device that provides effective ventilation of the shoe, to avoid excessive and unwanted sweating of the foot.

Furthermore, a task of the present invention is to limit the relative humidity of the air introduced into the shoe.

Furthermore, a task of the present invention is to make available a device capable of introducing a deodorant or perfumed substance inside the shoe that allows to eliminate the bad smell produced by excessive sweating.

Furthermore, a task of the present invention is to make available a device capable of benefiting the user even while the latter is at rest, that is, while it does not operate the pumping device through the movement of the foot.

A further task of the present invention is to provide a shoe capable of ensuring effective internal ventilation and thus avoiding excessive and unwanted sweating of the foot.

The object and the tasks indicated above are achieved by a device for internal shoe ventilation according to claim 1 and by a shoe according to claim 11.

The features and additional advantages of the invention will result from the description, made below, of some examples of embodiments, given for information only and not limitative with reference to the attached drawings in which:

- Figure 1 schematically represents a sectional view of a shoe according to the invention;

- Figure 2 schematically represents a sectional view of a device for internal ventilation of a shoe according to the invention;

Figure 3 schematically represents the section along the line III-III of Figure 2;

- figure 4 schematically represents the section along the line IV-IV of figure 2;

- Figure 5 represents a perspective view of an embodiment of the device according to the invention;

- Figure 6 represents a perspective view of another embodiment of the device according to the invention;

- Figure 7 represents a sectional view of a further embodiment of the device according to the invention.

The present invention relates to a device 20 for internal ventilation of a shoe 10, whereby a shoe is meant any type of shoe, be it low or high or sports or walking.

The description of the device 20 and of its individual components which will be made hereinafter refers to a shoe 10 used correctly. In particular, the front part will identify the part of the device, or of the single components, relatively closest to the tip of the foot, while the back part will indicate the part of the device, or of its single components, relatively closest to the heel. Similarly, the upper part will refer to the part of the device, or of the single components, relatively more distant from the ground, while the lower part will refer to the part of the device, or of the single components, relatively closest to the ground. In a similar way, the upstream and downstream references will be understood with respect to the inlet 12 of the device 20 (which will be described in detail below): upstream it will identify a position relatively close to the inlet 12, downstream it will identify a position relatively far from the inlet 12, along the path defined for the air by the device 20.

With reference to figures 1 and 2, the device 20 includes a pumping unit 40 suitable for sucking air from the outside towards the inside of the shoe 10; an inlet chamber 70 suitable for introducing the air sucked by the pumping unit 40 inside the shoe 10; and a connection channel 50 suitable for conveying the air sucked in by the pumping unit 40 towards the intake chamber 70. The device 20 is further characterized in that it comprises hygroscopic means 36 suitable for reducing the degree of relative humidity of the injected air inside the shoe 10.

The device 20 can be made in its entirety from two half-shells, for example in polyether polyurethane, obtained by injection through a mold. These half-shells can be subsequently welded together. Welding can take place in a known manner in high frequency, with a brass electrode system, along their perimeter edge 52 (see attached figures).

In other embodiments, the device 20 can be made with different technologies, for example the individual components of which it is composed, i.e. a pumping group 40, a connection channel 50, an intake chamber 70, can be made separately from each other and connected by interference, gluing and the like.

In the following, reference will be made to the embodiment of the device 20 comprising the two half-shells. This embodiment can advantageously avoid that there are pressure drops in correspondence with the connections between the various components.

The pumping unit 40, with reference to the attached figures, is preferably positioned in correspondence with the heel of the shoe 10 in order to advantageously exploit, as will be described below, the movements that the foot makes during walking or running. The pumping unit 40 can comprise, in accordance with Figures 1 and 2, an inlet 12, an inlet conduit 14, a first non-return valve 16, a pumping chamber 18 and a second non-return valve 22.

The inlet 12 through which the device 20 communicates with the external environment can be arranged either in correspondence with the separation line between the sole 80 and the upper 90 or in a wall of the sole 80 or in the rear part of the upper 90 of the shoe 10. In particular, the rear part of the upper is the one corresponding to the buttress of the shoe. Figures 1 and 2 show a particular embodiment in which the inlet 12 is arranged in the rear part of the upper 90 of the shoe 10.

A waterproof and breathable polyurethane membrane can be found at the entrance 12. A membrane of this type is marketed by W. L. Gore & Associates under the Gore-Tex® brand. This membrane allows air to flow from the outside to the inside of the shoe and prevents the passage of water from the outside to the inside.

A filter can also be associated with input 12 (not shown in the attached figures). This filter prevents an accumulation of impurities such as dirt, dust and / or mud from obstructing the inlet 12 in such a way as to affect the functionality of the device 20. Furthermore, said filter prevents impurities from penetrating inside the shoe 10. The inlet 12 can have a contour made of rigid or semi-rigid material of any shape. This outline, which will be visible in the shoe, can also be used to create an aesthetic motif in the shoe itself. The attached figures show a particular embodiment of the entrance 12 in which the relative outline has a triangular shape.

Downstream of the inlet 12, an inlet conduit 14 can be provided. This conduit 14 has the function of putting the inlet 12 in communication with a first non-return valve 16 of the pumping unit 40. The conduit 14 causes the air coming from the outside of the shoe 10, through the inlet 12, is directed to the first non-return valve 16. Said valve 16, in a per se known manner, allows the air to flow only in the direction indicated by the arrow X in figure 1. Downstream of the non-return valve 16, there can be a pumping chamber 18. Said pumping chamber 18 in the embodiments of the device illustrated in the attached figures, has an oblong shape and is located in correspondence with the heel of the shoe 10 This pumping chamber 18 can vary its shape alternatively from a crushed condition to a rest condition, creating inside it a depression such as to draw air from the outside of the shoe 10 and vice versa. rsa. The crushing condition occurs when the user places the weight of his body on the heel, while the rest condition occurs when the user places the weight of his body on the metatarsal and toes.

In accordance with an embodiment (see Figure 7), inside the pumping chamber 18 a sponge 42 made of polyurethane foam polyether material or similar materials with an open cell structure can be inserted. This sponge 42, consequently, allows the flow of air inside the pumping chamber 18 and can perform, at the same time, a cushioning function. The sponge 42 allows, in fact, to cushion the impacts that the heel of the foot receives every time the heel of the shoe 10 rests on the ground.

The pumping chamber 18 can be replaced by a pump of suitable power and size operated by a battery.

Downstream of the pumping chamber 18, a second non-return valve 22 can be arranged. This second valve 22, in a per se known manner and similarly to what is performed by the first non-return valve 16, allows the air to flow from the chamber. pumping pump 18 to a connecting channel 50 in a single direction, identified by the arrow X in Figure 1.

This channel 50 allows the air expelled from the pumping chamber 18 and flowed through the second non-return valve 22, to reach the inlet chamber 70.

The connecting channel 50 can be made of polyether polyurethane or similar materials.

An embodiment of the device 20 can provide for the insertion, inside the connection channel 50, of a Venturi tube 60 (see Figures 1 and 2). This Venturi tube 60, of a per se known shape, comprises a converging section 26, a section with a constant cross section 28 and a diverging section 30. In the converging section 26 the Venturi duct passes from an initial section Ai to a final section A2 in which AI > A2; the section with constant section has a section equal to A2; the diverging section 30 passes from an initial section A2 to a final section A3 in which A2 <A3. The Venturi tube 60 has the function of increasing the pressure of the air flow inside of the connection channel 50. This allows easier expulsion of the air present inside the intake chamber 70, according to the methods described below.

In a further embodiment, a small tank (not shown in the attached figures) containing a perfumed substance or deodorant can be associated with the Venturi tube 60. The depression created inside the air flow in correspondence with the constant section section 28 can be used to suck the perfumed substance from the tank.

The connection channel 50, in a further embodiment of the device 20, can have one or more holes at its upper surface.

In this way, if a perforated shank (0 shank) is associated with the device 20, part of the air sucked in from the outside by the pumping unit 40, and flowing inside the connection channel 50, can be introduced inside. of shoe 10 in correspondence of the plantar arch area.

Downstream of the connection channel 50, there is an inlet chamber 70. This inlet chamber 70 has the task of introducing into the shoe 10, the air received from the connection channel 50. In an embodiment of the device 20, said inlet chamber 70 is located in the anterior region of the sole of the foot. It consists of two oblong half-shells.

The inlet chamber 70 can have at least one opening 34 at its upper surface. Through this opening 34 the air collected inside the intake chamber 70 is introduced into the shoe 10. In one embodiment, with reference to the attached figures, there is a plurality of openings 34 in correspondence with the upper surface of the shoe. intake chamber 70. This ensures that there is no possibility for the user to feel any discomfort. The presence of a single opening of significant size could in fact be perceived by the foot. The plurality of openings 34 is preferably arranged in the area of the toes, where sweating is usually greater.

The device 20 according to the invention comprises hygroscopic means 36 suitable for reducing the degree of relative humidity of the air introduced into the shoe 10.

Said hygroscopic means 36 can be constituted by salts, silica gel, rice grains, wood shavings or similar substances. When they come into contact with the humid air sucked in from the outside of the shoe 10 by the suction unit 40, they are able to absorb or adsorb the water molecules present inside the air flow, reducing their degree relative humidity.

Said hygroscopic means 36, in one embodiment, consist of wood chips. Wood, in addition to having the advantage of being a natural element, unlike salts and silica gel, does not exhaust its hygroscopic power during the use of the shoe and therefore does not need to be replaced. In addition, the wood can be soaked in perfumed and / or deodorant substances which are then released into the flow of air directed inside the shoe.

The hygroscopic means 36, to prevent them from dispersing inside the device 20, can conveniently be included within a retina (not shown in the figure) or another container.

In an embodiment, see attached figures, the hygroscopic means 36 are contained inside the intake chamber 70. The air sucked in by the suction unit 40 passes through the connection duct 50, enters the intake chamber 70 and, first to be introduced into the shoe 10 through the openings 34 present on the upper surface of the intake chamber 70, it comes into contact with the hygroscopic means 36.

In a further embodiment (not shown in the attached figures) the hygroscopic means 36 can be inserted inside the connection channel 50. In this case the relative humidity degree of the air flow passing through the channel is reduced. connection 50. If the upper surface of the connection duct 50 has openings, the dehumidified air can be partly introduced in correspondence with the plantar arch area, and partly be directed, as previously described, into the chamber 70. If further hygroscopic means 36 are present inside the intake chamber 70, the flow of air sucked in from the outside will undergo, before being introduced into the shoe 10, a further reduction of its degree relative humidity in correspondence of the intake chamber 70.

The operation of the device 20 according to the invention will be briefly described below, with reference to the phases in which the walking cycle can be broken down, where the walking cycle is understood to mean the set of movements comprised between two successive initial contacts to the ground of the same foot.

In a known way, 4 phases can be identified in the walking cycle:

- heel contact: phase in which the heel of the foot projected forward is in contact with the ground;

- full support: phase in which the foot is completely resting on the ground and the detachment of the other foot from the ground begins;

- heel detachment: phase in which the heel of the supporting foot detaches from the ground and the other foot touches the ground;

- detachment of the fingers: phase in which the detachment of the fingers from the ground occurs, after which the weight of the body is transferred forward.

In correspondence with the four phases described above, the operation of the device 20 according to the invention can be broken down into the following phases:

ventilation

- idle rest

aspiration

full rest

The ventilation phase occurs in conjunction with the heel contact phase.

When the heel of the foot projected forward comes into contact with the ground, the pumping chamber 18 is compressed under the weight of the user's body, reaching the crushing condition and expelling all the air trapped inside. The air flows through the connection channel 50 and reaches the intake chamber 70.

The first non-return valve 16 prevents the air contained inside the pumping chamber 18 from being expelled towards the outside of the shoe 10.

The second non-return valve 22 prevents the air from flowing back from the connection channel 50 to the pumping chamber 18, in the opposite direction to the direction indicated by X in figure 1.

The air flow expelled from the pumping chamber 18 comes into contact with the hygroscopic means 36 which can be located, as previously described, inside the connection channel 50 or inside the intake chamber 70 or in both components of the device 20.

The air which, following contact with the hygroscopic means 36 has a lower degree of relative humidity than when it was introduced into the device 20, is introduced into the shoe 10, in the direction indicated by Y in figure 1.

The empty rest phase occurs in conjunction with the full support phase. The entire device 20 is compressed by the weight of the user's body. The pumping chamber 18 remains in the crushed condition and there is no air flow inside the device 20.

The suction phase occurs in conjunction with the heel detachment phase.

When the user lifts the heel, the pumping chamber 18 ceases to be compressed and begins to expand to return to the rest condition.

The expansion of the pumping chamber 18 determines an internal depression that allows air to be sucked in from the outside.

The air sucked in through the inlet 12, flows into the inlet duct 14 and through the first non-return valve 16 reaches the pumping chamber 18.

The latter regains the oblong shape it had before being compressed by the force exerted by the user's foot and reaches the rest condition.

The full rest phase occurs in conjunction with the toe release phase if the user is walking or running.

The pumping chamber 18 is in the rest condition and has accumulated inside the air that will be expelled in the subsequent ventilation phase.

Inside the device 20 the air flow ceases.

The full rest phase also occurs whenever the user, while wearing the shoe, does not operate the pumping device through the movement of the foot.

This occurrence occurs, for example, when the user is seated. In this case, in fact, the pumping chamber is in the rest condition. Any compression exerted by the weight of the user's foot is negligible and does not involve the operation of the pumping unit 40.

In this case, the presence of the hygroscopic means 36 can, even in the absence of a flow of air from the outside to the inside of the device 20, help reduce the degree of relative humidity present inside the shoe 10.

Through the openings 34 made in the inlet chamber 70 or in the connection channel 50, in fact, the inside of the shoe 10 communicates with the device 20 and consequently the hygroscopic means 36 can absorb or adsorb the water molecules present inside. of shoe 10.

As previously described, an embodiment of the device 20 provides for the insertion of a Venturi tube 60 inside the connection channel 50.

With reference to the ventilation phase, the insertion of a Venturi tube 60 allows to increase, in the convergent section 26, the speed of the air flow. The sucked air flows more rapidly inside the connection duct 50 and reaches the intake chamber 70. The reduction of the travel times of the connection duct 50 by the sucked air flow, means that the intake to the the interior of the shoe 10 takes place before the subsequent suction phase begins and consequently the propulsive force exerted by the compression of the pumping chamber 18 by the user's foot ceases.

In addition, the insertion of a Venturi tube 60 allows, in the divergent section 30, to increase the pressure of the air flow.

Consequently, since the Venturi tube 60 is positioned in the vicinity of the intake chamber 70, the introduction of the sucked air into the intake chamber 70 is facilitated.

Furthermore, a small tank containing a perfumed or deodorant substance can be associated with the Venturi tube 60. The depression created inside the air flow in correspondence with the constant section section 28 can be used to suck this substance from the tank which mixes with the air flow sucked from the outside.

Consequently, an air flow can be introduced inside the shoe 10 which in addition to having, following contact with the hygroscopic means 36, a relative humidity degree lower than when it was aspirated, is also perfumed and / or deodorized.

An embodiment of the device 20 provides, inside the pumping chamber 18, the insertion of a sponge 42.

On the one hand, this sponge 42 performs a cushioning function by cushioning the impact that the user's heel receives whenever the foot rests on the ground, on the other hand, with reference to the suction phase, it allows a more rapid expansion of the pumping chamber 18.

In this way, even if the user is engaged in a stroke and consequently the succession of the various operating phases of the device 20 is accelerated, the pumping chamber 18 can expand completely reaching its rest condition. If the pumping chamber 18 were compressed before reaching its rest condition, an air flow rate lower than that allowed by the pumping chamber 18 capacity could flow inside the connection channel 50, with a consequent reduction of the device efficiency 20.

A further embodiment of the device 20, not shown in the attached figures, provides for the insertion of the Venturi tube 60 in the connection channel and the use, inside the pumping unit 40, of two non-return valves 16, 22 which allow, in a per se known manner, the flow of air in a single direction, opposite to the direction indicated by the arrow X in figure 1. In this case, the intake chamber 70 can act as an intake chamber for the air present inside the shoe 10. The air can then flow into the connection duct 50 and, through the non-return valve 22, into the pumping chamber 18. From there, through the non-return valve 16 , can reach the inside of the duct 14. The air channeled inside the duct 14 can be subsequently expelled towards the outside of the shoe through the inlet 12.

As it will appear clear to the expert, introducing a flow of air with a low degree of relative humidity into the shoe allows you to keep the environment inside the shoe ventilated and hygienically clean and dry.

Furthermore, a further advantage of some embodiments of the present invention is represented by the fact of being able to introduce a flow of perfumed air into the shoe. This allows you to eliminate or at least reduce the bad smell that may occur inside a shoe.

A further positive effect is represented by the fact that even in the absence of movement, i.e. without the compression and discharge of the pumping chamber by the user, the hygroscopic means present inside the device and in communication with the inside of the shoe through the openings described above, they can dehumidify the air inside the shoe, ensuring high comfort.

The skilled person may, in order to meet specific needs, make changes and / or replacements of the elements described with equivalent elements to the embodiments of the ventilation device 20 described above, without thereby departing from the scope of the attached claims,

Claims (11)

CLAIMS 1. Device (20) for internal ventilation of a shoe (10), comprising: a pumping device (40) suitable for sucking and expelling air - an intake chamber (70) suitable for introducing the air sucked by the pumping device (40) into the shoe (10) at least one connection channel (50) suitable for conveying the air sucked in by the pumping device (40) towards the intake chamber (70) characterized by the fact of including hygroscopic means (36) suitable for reducing the degree of relative humidity of the air introduced into the shoe (10). Device (20) according to claim 1 in which said hygroscopic means (36) are contained in the intake chamber (70). Device (20) according to any one of the preceding claims, in which said hygroscopic means (36) consist of wood shavings soaked in a perfumed and / or deodorant substance. Device (20) according to any one of the preceding claims in which said hygroscopic means (36) are selected from the group comprising: silica gel, salts, rice grains. Device (20) according to any one of the preceding claims wherein the pumping device (40) comprises an inlet (12); a filter and / or a membrane being coupled to this inlet (12). Device (20) according to any one of the preceding claims, wherein said connecting channel (50) comprises a Venturi tube (60). 7. Device (20) according to claim 6 wherein a tank containing a perfumed or deodorant substance is associated with said Venturi tube (60). 8. Device (20) according to any one of the preceding claims comprising a sponge (42) made of materials with an open cell structure, said sponge being inserted inside a pumping chamber (18). Device (20) according to any one of the preceding claims, characterized in that it is made in its entirety by two half-shells in thermoplastic material; said shells being obtained by injection through a mold and being welded together along their perimeter edge (52). Device (20) for internal ventilation of a shoe (10), comprising: - a suction chamber (70) suitable for sucking air from inside the shoe (10) a pumping device (40) suitable for sucking in and expelling air at least one connection channel (50) suitable for conveying the air sucked from the suction chamber (70) towards the pumping device (40) characterized in that said connection channel comprises a Venturi tube (60). Shoe (10) containing a device (20) for internal shoe ventilation according to any one of the preceding claims.