ITTV20080100A1 - LAYER OF SINUSOIDAL ELASTOPLASTIC MATERIAL, WITH FLUID AND VENTILATION CANALIZATIONS. - Google Patents

Description

LAYER OF ELASTOPLASTIC MATERIAL

SINUSOIDAL. WITH VENTILATION CHANNELS

AND FLUID FLOW

[0001] The present invention relates to a layer of sinusoidal elastoplastic material with channels for ventilation and outflow of fluids.

Field of application

[0002] The innovation finds particular, though not exclusive, application in the sector of production and marketing of bodies designed to favor ventilation and the controlled outflow of fluids, such as for example to improve the comfort of the foot in a worn condition, as well as as a mattress cover mat for long-term patients or also as rugs, such as, for example, those for pets, rugs for shower use and so on.

[0003] In the field of footwear, for example, it is known that the insole of the foot is the part, with the forehead and axillary area, with the greatest density of sweat glands. Even in an apparently invisible condition, an evaporative flow of liquid originates, consisting mainly of water, which is brought to the surface of the skin, where, once surfaced, it evaporates by dispersion / dilution in air.

[0004] The perception of general well-being of the foot, when fitting the shoe, is closely related to some aspects that find precise explanations in the thermodynamic and mechanical principles expressed below:

a) First of all, the microclimate surrounding the foot insole area must be able to allow adequate evacuation of the flow of sweat, through the exchange of the underlying air;

b) The temperature of the parts in contact with the plantar area must be as close as possible to the temperature of the plantar area;

c) The cooling of the plantar area, caused by poor insulation of the insole, otherwise determines a condensation of sweat in the superficial part of the skin or in the parts near the insole, favoring the perception of the â € œwet footâ € effect; d) Significant sweating also occurs in conditions of low physical activity, e.g. while driving a car, as it is promoted not only by the most obvious need to dispose of the heat generated by physical activity or by climatic conditions, but also by psychic hormonal stimuli or by the intake of different substances. In fact, in this situation, the relative air circulation that is established in conditions of mobility is further reduced, which combined with a reduced metabolic activity, reduces the ability to compensate for the heat dispersed in conditions of unfavorable thermal insulation of the plantar area, making it more easily sensitive to the lowering of the temperature caused by the contact with the insole of the shoe, giving rise to the perception of the â € œwet footâ € effect.

[0005] It is generally known that the foot must rest on a sufficiently soft surface to allow an ergonomic and pleasant distribution of the load to which it is subjected. At the same time, the structure of the insole should be made of materials capable of not absorbing humidity to prevent bad odors from developing with processes triggered by bacteria.

State of the art

[0006] The drawback described above, for example, seems to have been partially solved by patent application no. IT2003A00001 0 (Low) which describes a stratified insole for internal ventilation and the control of the microclimate of a shoe, which is made up of the following layers of material, one superimposed and coupled to the other:

a) A first lower support layer made of semi-rigid and transpiring material;

b) An insulating component of pre-coupled material, joined to said first by the interposition of a layer of polyester cloth, composed of a second and third layer obtained in a SEBS block copolymer, in which at least the second layer in correspondence with the The coupling interface to the third layer provides for a plurality of channels, the separating baffles of which have an enlarged base, which extend longitudinally from the front to the rear of the insulating component possibly affected by transverse connection channels; while the third layer provides, at the coupling interface to the fourth layer, longitudinal channels and perpendicular holes for connection with the channels of the second layer;

c) A fourth layer of material, joined to the insulating component on the right side! third layer, made of breathable material.

[0007] In the mentioned patent application, a concept of ventilation is introduced along the longitudinal axis of the insole, where, however, the thermal conductivity remains high due to the considerable support surface of the sole of the foot to the parts of non-expanded thermoplastic. In other words, the indirect connection that is established, from the sole of the foot crossing the insole, reaches the sole, forming a thermal bridge. From a practical point of view, this favors an unfavorable condition in terms of moisture condensation. Furthermore, it is noted that the ventilation channels, developed mainly in the longitudinal direction, have the defect of limiting air changes.

[0008] IT1 288658 (Low) suggests a shoe, which includes a technical climate-controlled sole structure, in which the upper is associated with a sole after the interposition of a layered insole, in which at least one layer is treated with anti-mold and anti-bacterial sanitizing products, said insole, being obtained through the association of a first layer of thermoplastic material whose shape creates channels, and to which a second layer is associated, consisting of a layer of coconut fiber and then finally providing a third element composed of a leather shape; and in which the sole, in logical correspondence, provides intercommunicating holes with the outside, facilitating the circulation of air through said insole.

[0009] A ventilated insole is also described in GB2250417 (Chao). The proposal provides for an upper layer and a lower layer made of foamed material, where the lower layer and the upper layer are joined to each other with adhesive, and cut according to the shape of a shoe. The adhesive surface, in correspondence with the lower layer, has longitudinal and transverse connection and ventilation grooves which extend from the edge of the lower layer to the rear part of the lower layer. In correspondence with the termination of the furrows, recesses are also obtained from the stratified insole in order to avoid the occlusion of the ends of the furrows from contact with the edge of the inner wall of the sole, thus allowing a correct evacuation of the air. The rear part of the insole has an elongated shape and lies in a position close to the opening of the shoe in such a way as to avoid occlusion by the internal walls of the shoe, ensuring the ventilation effect. The upper layer can be obtained with a series of circular holes corresponding to the underlying grooves of the lower layer in order to make the ventilation passage system more efficient.

[0010] In DEI 9715097 (Usui et al.), Sole elements are provided, obtained in block copolymers according to the sequence A-B-A where A is of styrene.

US4438573 (McBarron) discloses a ventilated athletic footwear. A resilient sole in correspondence of the coupling interface to the insole, is obtained with a plurality of channels in the longitudinal and transversal direction to form a network and is in communication with the insole through perpendicular holes.

[0012] ITTV2007A000157 (Zanetti) suggests a breathable insole device, preferably perforated, in contact with the lower part of the foot and the shoe with the relative insole, preferably comprising a breathable insole, for example in natural leather, optimal for its ability to absorb perspiration which also performs the function of uniforming the punctiform surfaces of the underlying monolithic support and compensation element joined to the slab; where the monolithic support and compensation element, in thermoplastic material, obtained by hot injection, has large empty spaces, in its reticular structure, optimizing the ratio of mass used / volume created, and in which the punctiform surface in contact with the slab it has small protrusions, said punctiform surface in contact with the slab being between 15% and 40% of the total surface.

[0013] US6455123 (Poe) describes an anti-slip mat made of rubber or the like covered with a sheet of elastomeric material. The mat is provided with a plurality of holes and foresees in correspondence of the upper facade of the ribs in relief. CA1078086 (Iwama) describes a gel of an elastomeric block copolymer, which can be used as an insulator and mattress for long-term patients. The ventilation function of the mattress cover is provided in US3859678 (Davis).

State of the art close to the found

[0014] D1: IT12491 35 (Farabollini) proposes a sole for shoes with internal channeling. The sole has transversal channels which in the central part appear deeper than the ends of the channels. The sole is joined by an insole which only in the front part is provided with a multitude of holes in communication with the transverse channels.

[0015] D2: US2007 / 0028485 (Crane et al.) Discloses a removable insole adapted to be inserted into a shoe. Figure 7 shows a portion of the insole which includes transversal ribs projecting sinusoidal on a horizontal plane, slightly distant from each other in such a way as to obtain ventilation channels. The main purpose of these ribs is above all to exert a shock-absorbing function during the pronation of the foot while helping walking thanks to the significant elastic return effect originated by the sinusoidal conformation of the ribs, similar to a spring. The material with which the insole is made is a thermoplastic elastomer, such as the polymeric material of the Kraton family; styrene, rubber olefins, block copolymers, thermoplastic polyurethanes, thermoplastic polyolefins, polyamide, polyureas, polyesters and more. The optimal material seems to be the block copolymer possibly added to the matrix with mineral oil as plasticizer.

[0016] D3: US5469639 (Sessa), proposes a sole for footwear with an insert provided with a shock-absorbing cushion function. The material with which the insert can be obtained is TPR or thermoplastic rubber. In Figure 5, a sole is represented, with the insert inside, which, transversely, is provided with parallel ribs with sinusoidal development, on a vertical plane, in correspondence with the coupling interface to the sole.

[001 7] It is therefore reasonable to consider that it is known:

â – ¡An insole, a mat or a mattress cover made of an elastomer, for example a block copolymer;

â – ¡An insole that is provided with transversal and longitudinal channels with respect to the insole;

â – ¡An insole, a mat, of the type provided with holes for aeration or outflow of the fluid also in communication with the ducts;

â – ¡An insole or insert which transversely presents ribs with a sinusoidal course on a vertical plane; â – ¡An insole with the aforementioned characteristics which at least locally achieves the function of a shock absorber.

[0018] In the light of the aforementioned considerations, it is the applicant's opinion that at least known insoles do not yet confer an optimized function that combines the effectiveness in ventilation at the sole of the foot and generally inside the shoe, with a function that achieves the effect of shock-absorbing cushion during the exercise of walking and sporting practices and more generally provided with greater comfort of the shoe.

Drawbacks

[0019] According to a first opinion of the applicant, the main drawbacks of traditional insole systems are the following. The insoles made of expanded materials, although in the part in contact with the foot in leather or other breathable materials, are in fact not very effective since the breathable material ceases its effectiveness after a short time. In other words, this occurs when the underlying part is unable to dispose of the humidity transmitted, both due to the absence of an effective ventilation system, and to the limited vapor permeability of the materials that base their elasticity. on the expansion of gas in micro bubbles within the structure of the thermoplastic material.

[0020] The interpretation of the European harmonized standard EN 344 dated 01/94 can be partly helpful in understanding the real needs. This standard establishes the requirements and, where appropriate, the test methods for verifying compliance with these requirements, of those footwear designed to protect the wearer's feet and legs against foreseeable risks in various work sectors. It can only be used in conjunction with EN 345-92, EN 346-92 or EN 347-92, which establish the requirements for footwear according to specific risk levels.

In the related test, in essence, it is considered that the insole must absorb at least 35% of water of its own weight. In general, it is known that expanded thermoplastic materials absorb water from 100% up to 250% of their weight, depending on the density level of the foam and the materials with which it is made. Consequently, it is understood that the foot will have to live together permanently, in an environment with high humidity, this is because after the expected period of desorption, the insole will have to get rid of at least 40% of the absorbed humidity. In practice, it is known that the insole will remain soaked and perpetually, at best, with at least 21% of its own weight of water. It goes without saying that the aforementioned circumstance can only give rise to intense bacterial activities that cause bad odors, as well as losing the valuable thermal insulation characteristics.

[0021] As regards the use of traditional non-expanded resilient materials, such as elastomers, if on the one hand a relative improvement of the characteristics given by the limited water absorption is obtained, on the other hand an increase is achieved of thermal conductivity giving rise to a more sustained cooling or heating of the foot, depending on the external climatic conditions, with a more accentuated perception of the effect of â € œcooked footâ € or â € œwet footâ €.

[0022] For example D2 and D3, which comprise inserts made of elastomer, if on the one hand they give good comfort, on the other hand they seem not to contemplate an effective ventilation function. In both solutions, it seems to be quite clear from the illustrations that the air can flow only in the direction of one of the two orthogonal axes, a circumstance that can obviously lead to reduced air circulation.

[0023] Companies in the sector, therefore, have for some time been oriented in this direction, with the main aim of seeking innovative solutions, often improvements, with respect to the pre-existing ones.

[0024] The purpose of the present invention is also to obviate the aforementioned drawbacks.

[0025] These and other purposes are achieved with the present innovation according to the characteristics of the attached claims, by means of a layer of sinusoidal elastoplastic material with ventilation and fluid outflow channels, in which:

a) the upper side and the base side have a corresponding punctiform surface, said punctiform surface being between 15% and 40% of the total surface of each side;

b) the point surface of each side has ventilation holes;

c) between the upper side and the base side there are ventilation channels, where said ventilation channels communicate with the first ventilation holes;

and again in which the layer of elastoplastic material is configured with sinusoidal shapes aligned by parallel rows and side by side by contiguous steps, each row being with the wave in phase opposition with respect to the wave of the adjacent row.

Aims

[0026] The object of the present solution has the advantage of drastically reducing thermal conductivity. This is the case, for example, of the application of the layer of sinusoidal elastoplastic material as an insole, allowing to achieve a greater overall surface available for the disposal of the humidity absorbed by the insole device in contact directly or indirectly with the sole and the sole of the feet.

[0027] A second result is that the layer of sinusoidal elastoplastic material when applied as an insole device in contact with the foot quickly reaches and easily maintains the temperature of the foot, avoiding the perception of the â € œwet footâ € or â € œfoot phenomenon. cottoâ € due to condensation from cooling or heating coming from the external environment.

[0028] A third object is achieved thanks to the perforated channels, obtained from the adjacent configuration of the sinusoids in opposition of phase. The said tubular channels allow to optimize the air circulation characteristics for convective ventilation, which is implemented in the phases of high mobility due to the compression / decompression of the free spaces in the tubular section of the elastic structure. In particular, the layer of elastoplastic material is able to deform progressively proportional to the load, returning to its initial position as soon as the load is removed. It is therefore the deformation that generates an escape of the underlying air, both from the side channels and from the upper holes, depending on the shape and level of deformation.

[0029] With the invention described, when applied to an insole device, at each step, air changes are obtained in the underlying part of each foot equal to the free volume that is compressed / decompressed greater than 50 cm <3> d ' air. Since the channels communicate with the insole by means of a dense network of holes, the evacuation of sweat generated by perspiration is easily disposed of, even in static conditions thanks to the free convective circulation of air that passes through the perforated tubes. In this case, in the absence of load, the ducts therefore allow for air circulation, so that in no point of the structure there are conditions of â € œaerobicityâ €. As for the thermoplastic material of which the elastoplastic material layer is composed, since it is preferably a block copolymer, for example SBS or SEBS, it is not hygroscopic by nature.

[0030] A significant feature is also constituted by the fact that in the lower support area of the structure there is no formation of perimeter closed areas, thus allowing the evacuation by gravity and runoff of any pollutants, thus avoiding the retention of liquids in particular that should invade the structure itself.

[0031] Another object is to be found in the fact that the layer of sinusoidal elastoplastic material offers an easy possibility of washing, sanitizing, sterilizing, being particularly suitable also for different uses, also having the particular characteristic that the areas potentially interested in possible pollution by liquids or solids, they are devoid of inlets or obstructive cavities, therefore without interstices that are difficult to clean / inspect, a need particularly felt in uses such as:

- Mattress overlay or mattress cover, or mat, improving the ventilation condition in correspondence with the support surface for contact with the human body, in particular for long-term patients;

- Mats, for example for pets, where existing products have a tendency to become impregnated with bad odors;

- Carpets, for example for shower use, favoring the flow of water and giving a good friction surface with non-slip purposes.

[0032] In conclusion, it has become possible to obtain a layer of sinusoidal elastoplastic material of a valuable nature, in which, the conformation of the elastic / resilient sinusoids, also produces a significant attenuation of the impact, such as for example in the support phase of the shoe, anti-shock effect. In this case, thanks to the dynamics of the movement of the foot, which, resting in the heel area, therefore through the subsequent deformation of the insole structure, generates a geodynamic massage with a significant benefit in promoting better blood circulation and greater fluidity of the articulation of! feet. In other words, a product with a good technological content is obtained, improving the offer on the market for the company with a containment of construction costs. In relation to this last aspect, it is noted that the layer of sinusoidal elastoplastic material is made through the injection of thermoplastic material into a mold that does not need mobile carriages as the ventilation channels are obtained as a result of the intersections of the sine waves of the mold.

[0033] These and other advantages will appear from the following detailed description of a preferred embodiment solution with the help of the enclosed schematic drawings, the details of which are not to be construed as limiting but only as examples.

Contents of the drawings

Figure 1 represents an axonometric view of the layer of sinusoidal elastoplastic material;

Figure 2 is a longitudinal sectional view of the layer of sinusoidal elastoplastic material shown in Figure 1;

Figure 3 is a detailed view of the detail A shown in Figure 2;

Figure 4 is a plan view of an insole device made with a layer of sinusoidal elastoplastic material; Figure 5 is a longitudinal sectional view of the insole device of Figure 4;

Figure 6 is a sectional view relating to detail A of Figure 5, in the portion corresponding to the support of the heel of the insole device;

Figure 7 is a sectional view relating to detail B of Figure 5, in the portion corresponding to the support of the metatarsal and phalanges of the insole device;

Figure 8 is an isometric view of a cover for an insole device;

Figure 9 is a cross-sectional view of the insole device obtained from a layer of sinusoidal elastoplastic material;

Figure 10 is a cross-sectional view of the assembly, consisting of the insole device obtained with a layer of sinusoidal elastoplastic material of Figure 9 to which the lining of Figure 8 is joined.

Practical example of embodiment of the invention

[0034] The layer of sinusoidal elastoplastic material (10), (Figure 1) is obtained from an elastomer, more particularly from thermoplastic material for hot injection, such as for example a block copolymer of the SEBS type (styrene-ethylene-butylenestyrene ) or SBS (styrene-butylene-styrene). It is configured with sinusoidal shapes aligned in parallel rows (a, b, c, d ...) side by side in contiguous steps, each row being with the wave (11a) in phase opposition with respect to the wave (11b ) of the adjacent row.

[0035] Each wave (11a, 11b, 11c, 11d) has at least one central hole (20, 21) which passes perpendicularly to the wave (11a, 1 1b, 11e, 11d), obtained in correspondence with the portion curved, both in the convex and concave position (Figure 3). In this way, the holes (20, 21) are parallel to each other and uniformly distributed, both in correspondence with the upper side and the lower side of the layer of sinusoidal elastoplastic material (Figs. 1, 2). The portion of the surface that remains peripherally with respect to the holes (20) made in correspondence with the upper side (Fig. 1) and for each wave (11a, 11b, 11e, 11d) constitutes the point-like surface (40) for supporting the plant of the foot and which in the present case is between 15% and 40% of the total surface of each of the two sides, respectively upper and lower of the layer of sinusoidal elastoplastic material (1 0).

[0036] The juxtaposition by parallel rows (a, b, c, d ...) of the sinusoidal shapes with the waves (11a, 11b, 11c, 11d) in opposition of phase, gives rise to the ventilation channels (30) with solution of continuity, parallel to each other, substantially orthogonal to the rectilinear projection of the sinusoidal shapes of each row (11a, 1 1 b, 11c, 1 1d). Said ventilation channels (30) which are therefore open, alternately now upwards and then downwards, are also in communication with at least one of the two sides, respectively upper or lower, of the layer of sinusoidal elastoplastic material (10) for through the holes (20, 21).

[0037] Figure 4 represents an insole device (100) obtained from a layer of sinusoidal elastoplastic material similar to the sinusoidal elastoplastic material layer (10) of which in Figure 1. More in detail, the insole device has an essentially a shape of the sole of the foot, with an enlarged front part that is suitable for supporting the phalanges and the metatarsal part, a tapered intermediate part that affects the flexion of the foot, followed by a rear part in correspondence with which the heel rests . The surface of the insole (100), both that referred to the upper side (Figure 4) and that referred to the lower side (Fig. 6 and 7), is perforated by the multitude of holes (20, 21) passing perpendicularly, distributed in the case of species in a uniform way but also being able to be localized for distinct areas, in such a way as to be in communication with the surrounding environment. The holes (20, 21) are in communication with the ventilation channels (30) which result from the sinusoidal shapes aligned in parallel rows (a, b, c, d ...) side by side in contiguous steps, each row being with the wave (11 a) in phase opposition with respect to the wave (11 b) of the adjacent row.

[0038] In the case of the insole device (100) shown in Figure 4, it can be observed how the elasticity can be changed locally, simply by configuring the shape of the wave (11a) differently, as an alternative to the uniformly distributed wave solution (11a) for the entire surface of the same. More in detail (Figure 7), the wave (12a) of the anterior portion of the insole device (100) appears to be with the arc more elongated and therefore less accentuated than the arc of the wave (11a) which concerns the rear portion of the insole (100), in such a way that with respect to each part of the latter a resilient capacity is given in proportion to the actual load to be supported. On the practical side, this also entails a proportional thinning of the insole device (100), as the sinusoidal shape develops from the back towards the front, resulting (see Figure 5) the front part with a substantially lower thickness than the rear. This configuration can also be modified in combination with a variation in the thickness of the thermoplastic material that forms the sinusoid.

[0039] Again, the insole device (100) is peripherally surrounded by a wing-like edge (50) (see Figs. 4, 6) which protrudes orthogonally in cantilever respect to the underlying lower side of the insole device (100) . In this way, along the edge (50) that circumscribes the insole device (100), there are substantially equidistant circular holes (51) (Fig. 4), which are positioned along the two sides, neglecting the part relating to the heel vault. and part of the tip. The area that is thus defined within the perimeter of the edge (50), provides a surface that is punctiform (40) and is provided with ventilation holes (20, 21) aligned and of small dimensions having the same diameter. Clearly, by varying the number and configuration of the waves (11a, 11 b, 12a, 12b), it is possible to modify the percentage of surface of the insole device (100) in contact with the lower side of any insole or the plant of the foot itself, up to values equal to or close to 40%. As regards the small holes (20, 21), it is noted that they pass through the upper side to communicate with the ventilation channels (30), obtained transversely with respect to the longitudinal axis of the insole device (100).

[0040] The assembly of the insole device (100), (see Figure 9), can provide that the insole (100) is fitted with a covering (200) in the form of a sheath or pant (Figure 8), which is mounted over the insole ( 100) (Fig. 10) through a transversal slot near the lower part (201) of the upholstery (200), it allows to use different types of material especially for the part in contact with the foot, such as Alcantara, cotton, technical nets and fabrics, natural fibers, leather, according to the user's needs.

[0041] as regards other possible destinations, the layer of sinusoidal elastoplastic material (10) can be obtained each time of the desired shape or alternatively be punched to the desired shape and finally possibly coated with finishing material.

Legend

(10) layer of sinusoidal elastoplastic material

(a, b, c, d ...) sinusoidal shapes

(11a, 11b, 11c, 1 1d) wave

(12a, 12b) wave

(20, 21) central hole

(30) ventilation channels

(100) insole device

(50) edge

(51) circular holes

(40) point surface

(200) sheathing element

(201) lower side of the liner

Claims (6)

CLAIMS I) Layer of elastoplastic material with ventilation and fluid outflow ducts, in which: a) the upper side and the base side have a corresponding punctiform surface (40), said punctiform surface being comprised between 15% and 40% of the total surface of each side; b) the point surface (40) of each side has ventilation holes (20, 21); c) between the upper side and the base side there are ventilation channels (30), where said ventilation channels (30) communicate with the ventilation holes (20, 21), characterized by the fact that the layer of elastoplastic material (10) is configured with sinusoidal shapes aligned by parallel rows (a, b, c, d ...) and next to each other by contiguous steps, each row (a, b, c, d ...) being with the wave (11a, 11b, 11c, 11d) in phase opposition with respect to the wave (11a, 11b, 11c, 11d) of the adjacent row. 2. Breathable insole device, obtained with the layer of elastoplastic material (10) according to claim 1, characterized by the fact that it has a shape similar to the sole of the foot, with an enlarged front part which is suitable for supporting the phalanges and of the metatarsal part, a tapered intermediate part that affects the flexion of the foot, followed by a posterior part in correspondence with which the heel rests; the surface of the insole (100), both that referred to the upper side and that referred to the lower side being perforated by holes (20, 21) passing perpendicularly and in communication with the ventilation channels (30) which result from the sinusoidal shapes aligned in rows parallel (a, b, c, d ...) adjacent coplanar for contiguous steps, each row being with the wave (11a) in phase opposition with respect to the wave (11b) of the adjacent row. 3. Breathable insole device, obtained with the layer of elastoplastic material (10) according to claims 1 and 2, characterized in that the wave (12a) of the front portion of the insole device (100) has a more elongated arch or less accentuated with respect to the arc of the wave (11a) which concerns the rear portion of the insole (100), so that with respect to each part of the latter a resilient capacity is conferred in proportion to the actual load to be supported. 4. Breathable insole device, obtained with the layer of elastoplastic material (10) according to the preceding claims, characterized in that the thickness of the insole device (100) decreases as the sinusoidal shape develops from the back towards the front, resulting in the front with a substantially lower thickness than the back. 5. Breathable insole device, obtained with the layer of elastoplastic material (10) according to the preceding claims, characterized in that it is peripherally surrounded by a wing-like edge (50) which protrudes orthogonally in cantilever respect to the underlying lower side of the insole device (100), and in which along the edge (50) that circumscribes the insole device (100), there are circular holes (51) substantially equidistant, which are positioned along the two sides, neglecting the part relating to the vault of the heel and part of the toe. 6. Breathable insole device, obtained with the layer of elastoplastic material (10) according to the preceding claims, characterized in that the insole device (100) is fitted into the lining (200) in the form of a sheath or pant provided with a transverse slot near the lower part (201) of the cover (200).