RU2540391C2 - Multilayered insole to be inserted into footwear - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: invention relates to a multilayered insole (1) that is inserted into footwear or a boot (2), extends along the main stretching surface (1a) and contains: at least one damping element (7) fitted for damping mutual collision of the said boot (2) with the ground, extending mainly through the said insole (1) in the direction of the said main stretching surface (1a) and placed into the top part of the said insole (1); the said damping element (7) is characteristically represented by open pore foam plastic made of microporous PUR material, its time of 90% recovery after compression characteristically amounting to 0.3 - 2.5 sec; the insole additionally contains an air shock absorber (11) placed into the bottom part of the said insole (1) and having two plates (11a) designed so that to enable formation of an air-containing tight inflatable shell, as well as a third plate (11b) placed between the said two plates (11a) so that to enable division of the said inflatable shell into two individual shells and having through holes (11c) intended to ensure flow of air between the said two individual inflatable shells.

EFFECT: ensuring absorption of vibration and energy generated during a human's motion.

9 cl, 5 dwg

Description

The present invention relates to a multilayer insole embedded in shoes and the like, of the type described in the preamble of paragraph 1 of the claims.

It is known that currently shoe products, boots, etc. usually performed with the sole, cuff, insole and heel. The sole is part of the shoe in contact with the ground and is usually made of leather, rubber or plastic; the vamp forms the part surrounding the foot in its upper section, from the heel to the toes; the heel is a raised lower part located under the sole at the location of the heel of the foot; finally, the insole is an element that reproduces the shape of the foot, and is located inside the shoe and, in particular, on the sole and is adjacent to the inner surface of the vamp.

Shoes, like any other type of vestment, performs the function mainly of placement and support, is adapted to fulfill the function of a means of protection, to protect the foot from external factors such as cold and damp, without difficulty for foot movements and, thus, for normal walking.

In accordance with this, shoes should be, above all, soft and flexible; it should not be rigid and unbending and, accordingly, should not represent too severe a restriction of freedom for the foot, which impedes its natural movements.

In addition, people have to walk on hard surfaces such as asphalt, marble, tiles. These surfaces are not adapted to absorb the energy or vibration created when the shoe rests on the ground.

Accordingly, there is a return of these effects from shoes to a person who absorbs them almost in full. This circumstance can give impetus to the development of serious pathologies, such as tendonitis, tatalgia, periostitis, fatigue fractures, joint pain, especially in the feet, knees, ankles, back, and even to the base of the skull. For example, a study at the Charite University in Berlin showed that walking on flat surfaces is the root cause of postural deformities.

For the above reasons, it is important to have shoes that can provide not only comfort, but also the maximum ability to absorb the vibrations and energy that arise when a person moves, while ensuring the proper foot position and, as a result, the correct posture of the whole person. Therefore, the materials of which the shoes are made, and its shape, and, in particular, the sole and insole materials, which are elements that determine the ability of the shoe to absorb the above effects, are of the greatest importance.

One of the decisions made so far involves the use of air under pressure. In this solution, at least one sealed shell filled with air is located inside the sole, and, being deformed, this shell provides the possibility of absorption of the aforementioned energy.

In another solution, also based on the use of air, the sole is provided with an inflatable chamber, which communicates with the outer space by means of a valve. When walking people, the inflatable chamber alternately shrinks and expands due to the force of weight. This force creates an air flow through said valve and, consequently, a change in volume, which makes it possible to damp the said effect.

In another case, the use of springs is provided, which are suitably located in the heel area, while the springs, when subjected to weight, constantly change their length and, thus, produce an action that can limit the force exerted by the shoes on the foot.

Another solution provides for the use of multi-layer insoles. In this case, the manufacture of the insole is carried out by superimposing on each other a plurality of layers, each of which is designed to provide appropriate comfort for the user of the shoe. Each layer, therefore, has a specific thickness and / or is made of a specific material depending on the action that must be performed by it. The known solutions mentioned above have some important disadvantages.

In fact, they do not constitute a system capable of providing sufficient absorption of vibrations and energy, which pose a danger to humans.

In addition, the solutions described at the moment are subject to rapid wear and tear when used, whereby the advantages they offer quickly come to naught.

These decisions, mainly due to the large thickness, adversely affect the aesthetic appearance of shoes and, accordingly, can hardly be applied to elegant shoes. In particular, the multilayer insoles currently on the market are characterized by low efficiency.

In addition, the materials of which the multilayer insoles are made do not provide a feeling of great comfort due to the inappropriate “breathing” properties of the materials used.

In this situation, the technical problem underlying the present invention is to develop a multi-layer insole for laying in shoes, which can substantially eliminate the aforementioned disadvantages.

In the scope of this technical task, an important objective of the invention is to ensure the absence of transmission of voltage to a person by absorbing vibrations and energy that occur when the shoe comes into contact with the ground. Another important objective of the invention is to provide great comfort in all conditions of use of shoes. A further object of the invention is to provide a structure that is efficient, durable and inexpensive.

Not the most insignificant goal of the invention is to develop a multilayer insole, suitable for any type of shoe. The aforementioned technical task and the indicated objectives are achieved due to the multilayer insole for laying in shoes and the like in accordance with what is stated in paragraph 1 of the claims.

Preferred embodiments are described in the dependent claims.

Features and advantages of the invention will now be explained in detail with a detailed description of a preferred embodiment of the invention with reference to the accompanying drawings, in which:

Figure 1 is an exploded view of the claimed insole;

Figure 2 depicts the first section of the boot, essentially forming a vamp adapted to accommodate the insole;

Figure 3 - the second section of the boot, essentially forming a sole adapted to accommodate the inventive insole;

Figure 4 - method of using the inventive insoles;

Figure 5 - the insole shown in Figure 1 in the embedded position and ready for use.

With reference to the drawings, a multi-layer shoe insole according to the invention is generally indicated by 1. It provides the ability to create an element that is capable of absorbing energy and vibrations that occur when the shoe 2 touches the ground, preventing them from being transferred to the foot. In particular, the insole 1 absorbs energy and vibrations that are transmitted to the user's foot through the sole 3, i.e. through the part of boot 2, touching the ground.

In the presented embodiment, the sole 3 is formed with various elements and, in particular, it preferably contains many internal blocks or inserts 4 and component 5, which is equipped with housing elements adapted to accommodate a plurality of inserts 4.

Finally, the component 5 inside is attached to the lower portion of the vamp 6, i.e. to the area of the boot 2 surrounding the foot. The number of inserts 4 is preferably three: the first two, 4a and 4b, are made of absorbent material, such as expanded pore foam, and the third, 4c, is made of a polymeric material, such as polyvinyl chloride.

The first insert 4a is located in the front of the sole, while the other two 4b-c are on the back of the sole 3, i.e. in the area adapted to accommodate the heel. In particular, insert 4c is preferably located between insert 4b and component 5.

In the fabric 6, fabric 6a is preferably provided, for example a double fabric that is attached to the lower edge of the fabric, i.e. the edge, which is adapted for contact with the sole 3, and provides the ability to hold the inserts 4 in the housing elements available in the component 5.

The multilayer insole 1 is thus suitable for placement inside the shoe 2 and, in particular, has a lower surface in contact with the double fabric 6a and a side surface in contact with the scoop 6. It extends along the main surface of the stretch 1a and preferably contains at least three layers extending in the direction of surface 1a: a damping element 7, an upper layer 8 and a lower layer 9. The damping element 7 is a layer of material that successfully provides air passage and has a high absorption ability.

In an original way, said material forming the damping element 7 is preferably an open-cell foam of damping microporous polyurethane. In particular, this material is poron 62-red, marketed by Rogers Corporation, or a double layer containing the aforementioned poron 62-red.

In particular, it has high elasticity, providing minimal energy transfer to the user's foot during the expansion stage immediately following the contact of the boot 2 with the ground. Another important physical and mechanical feature of the material is its damping ability, i.e. he is able to absorb vibrations that occur at the moment of the mentioned contact, without transferring them to the foot.

Finally, the material used for the damping element 7 has elasticity, i.e. the ability to withstand impacts of about 4, measured using a test known as "ASTM D2632-92 Vertical Rebound," and is characterized by a 90% recovery time after compression corresponding to an interval of 0.3 s to 2.5 s. By the time of 90% recovery after compression is meant the time required for the material to undergo elastic deformation in the form of compression to recover 90% of the volume lost as a result of the above action.

A further feature of the mentioned material is a good “shape memory”, which allows to regain its original shape at the completion of the compression and expansion stages. Finally, this material is able to provide the necessary durability under any conditions of use of shoes 2 also due to its good resistance to abrasion and wear.

The damping element 7 is located in the upper part of the multilayer insole 1. In particular, the element 7 is located near the insole 1 portion so that when said insole 1 is embedded in the shoe 2, it is in direct contact with the foot or with the upper layer 8 in contact with the foot.

The damping element 7 essentially passes through the entire insole 1 in the direction of the main tension surface 1a and, thus, essentially refers to the entire contact area between the insole 1 and the foot, as shown in FIG.

Finally, the element 7 is a layer of a greater thickness than the adjacent layers, the thickness is from 2 mm to 6 mm, preferably about 3 mm In addition, in the contact zone between the foot and the insole 1, the upper layer 8 is located, it forms the supporting surface for the foot in the boot 2.

This top layer 8 is made of genuine leather or other similar material, suitable for forming a comfortable supporting surface for the foot and allowing air to pass through the insole 1. Finally, said upper layer 8 has a thickness in the range from 0.5 mm to 1.5 mm , said thickness is usually 0.8 mm.

The bottom layer 9 is located in the lower part of the multilayer insole 1 and is located under the damping element 7. This lower layer 9 thus forms the surface of the multilayer insole 1 in contact with the inside of the sole 2a of the shoe 2 when the insole 1 is embedded in the shoe. The bottom layer 9 is preferably made of a polymeric material, in particular ethylene-vinyl acetate. In order to ensure a suitable passage of air through the lower layer 9, at least one cavity 9a is formed in the front portion of said layer 9. Alternatively, instead of a cavity 9a, a plurality of holes can be made in the lower layer 9.

The bottom layer 9 provides for a flange 10 on the upper surface, and the flange 10 is made integrally with the aforementioned layer 9 and is located at least on the perimeter of the multilayer insole 1, preferably on the edge passing around the section of the insole intended for contact with heel of the foot. The flange 10 is a frame whose height makes it possible to include insole layers 1 lying on top of the lower layer 9, and the thickness provides greater stability to the user of shoes 2 equipped with this insole 1. Finally, the flange 10 and the lower layer 9 are preferably made in the form of an integral structure .

Under said lower layer 9, the multilayer insole 1 may be provided with an air shock absorber 11 configured to cover at least part of it and, in particular, that part of the insole 1 that is in contact with the heel.

The air damper 11 comprises two plates 11a interconnected in such a way as to form an airtight airtight inflatable shell, which is preferably divided into two separate inflatable shells by a third plate 11b.

Finally, a number of through holes 11c are provided in the plate 11b to allow air to flow between the two separate inflatable shells and thereby change the volume of the individual inflatable shell so as to at least partially absorb the effect on the shoe 2 in contact with the ground. The work of the multilayer insole 1, stacked in shoes, the design of which is described above, proceeds as follows.

As the sole 3 comes in contact with the ground, the insole 1 begins to deform elastically. In particular, the front portion of the damping element 7 begins to deform, and since it is subject to compressive forces due to the weight of the user, it begins to compress and, accordingly, absorb energy and vibrations resulting from the aforementioned contact.

As the contact spreads to the rest of the sole 3, the rest of the damping element 7 is also elastically deformed under compression and absorbs the aforementioned energy. This absorption action is finally facilitated by the presence of an air shock absorber 11, which undergoes deformation and constantly changes the location of the air inside itself, while the air can move inside a separate inflatable shell, as well as between two separate inflatable shells due to the presence of holes 11c.

Finally, the choice of material from which the damping element 7 is made provides the possibility of slow restoration of the insole 1 of its initial position, thereby minimizing the transfer of energy and vibration to the user's foot. This recovery time of the element 7, in all cases, is sufficient for the insole 1, so that the element 7 is completely out of the compressed state at the time of the next step and is again ready to absorb energy.

In addition, the deformation of the damping element 7 and the air shock absorber 11 allows the insole 1 to absorb any possible irregularities on the ground.

The invention provides important advantages. The insole provides excellent ability to absorb energy and vibrations occurring at the moment of contact of the boot 2 with the ground, as well as greater comfort. In fact, element 7 is made of a material that provides a sufficiently high rate of 90% recovery after compression, to such an extent that the energy transfer to the foot is minimized, but at the same time, to such an extent that the sole is allowed to come back to the fully extended position by the time of the next step, always with high damping ability.

In addition, the materials from which the insole 1 is made provide high durability of the insole 1. Further, the multilayer insole 1 provides the user with a high level of comfort due to its ability to absorb both the contact energy between the shoe 2 and the ground, and any possible irregularities on the ground.

The feeling of comfort is further enhanced due to the "breathing" ability of the insole 1, allowing air to pass, which allows to obtain optimal values of temperature and humidity inside the shoe 2. The advantage of this invention, which cannot be neglected, is that the insole 1 due to the physicomechanical features of the material Element 7 is suitable for the specific physiognomy of the user's foot.

Another advantage is that the insole 1 is generally thin, and thus it can be embedded in shoes of any type 2, even elegant shoes. An added benefit is the low manufacturing cost per insole 1.

The invention allows variations within the scope of the inventive concept. All parts can be replaced with equivalent elements, and materials, shapes and sizes can be of any grade and size.

Claims (9)

1. A multilayer insole (1) embedded in a shoe or boot (2) extending along the main tension surface (1a) and comprising: at least one damping element (7) adapted to dampen the impact of said boot (2) on the ground mainly passing through the entire insole (1) in the direction of the aforementioned main tension surface (1a) and placed on the upper part of the insole (1), characterized in that the said damping element (7) is an open-cell foam, made of a damping microporous polyurethane material, characterized by a 90% recovery time after compression of 0.3 s to 2.5 s, and the fact that the insole also contains an air shock absorber (11) placed in the lower part of the insole (1) and having two plates (11a) configured to form an airtight airtight inflatable shell, and a third plate (11b) placed between said two plates (11a), with the possibility of dividing said inflatable shell into two separate shells, and is made th with through holes (11c), designed to allow air to pass between said two separate inflatable membranes. 2. A multilayer insole (1) according to claim 1, wherein said material of said damping element (7) has an elasticity of about 4 when measured according to the test "ASTM D2632-92, Vertical Rebound". 3. A multilayer insole (1) according to claims 1 to 2, in which said material of said damping element (7) is adapted to allow air flow through said damping element (7) in a direction at right angles to said main tension surface (1a) . 4. A multilayer insole (1) according to claim 1, wherein said material of said damping element (7) has a thickness of 2 mm to 6 mm. 5. A multilayer insole (1) according to claim 1, comprising a lower layer (9) placed between said damping element (7) and an air shock absorber (11), with the possibility of contact with said boot (2), and containing a flange (10) placed at least on the perimeter of the insole (1) and suitable for improving the stability of the user. 6. A multilayer insole (1) according to claim 5, wherein said lower layer (9) comprises a cavity (9a) suitable for allowing said air flow to pass between said damping element (7) and an air shock absorber (11). 7. A multilayer insole (1) according to claim 5 or 6, wherein said lower layer (9) is made of ethylene-vinyl acetate. 8. A multilayer insole (1) according to claim 1, comprising a top layer (8) made of genuine leather and suitable for being placed on top of said damping element (7) and forming a supporting surface for the foot in said boot (2). 9. Shoes or boots (2), comprising a multilayer insole (1) according to one or more of the preceding paragraphs.

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