RU221218U1 - ORTHOPEDIC INSOLE - Google Patents

Abstract

The utility model relates to the field of medicine, in particular to orthopedic insoles for insertion into shoes, and can be used to correct foot deformities while walking. The technical result is an additional improvement in blood microcirculation in the foot. The orthopedic insole contains a base and supports located in rows on its lower side, and the height of each silicone support is calculated based on the degree of deformation of the user's foot, while the material from which the base and supports are made additionally contains glass microspheres in an amount of 5-10 g per one insole.

Description

The utility model relates to the field of medicine, in particular to orthopedic insoles for insertion into shoes, and can be used to correct foot deformities while walking.

BACKGROUND OF THE ART

Known from the prior art is an individual orthopedic insole for the correction of deformation of the arch of the foot, containing a base made of wear-resistant material forming the upper side of the insole, a base with a thickness over the entire surface of the insole from 1 to 2.5 mm, made of silicone monolithically with a base made of wear-resistant material, and adjacent to it has a silicone base with a thickness of at least 3 mm, as well as silicone supports made in the shape of a polygon with a difference in height and monolithically with a base made of wear-resistant material, a silicone base and an additional silicone base [RU218090 A43B 17/00, publ 05.05.2023 Bull. No. 13].

The closest to the claimed utility model is a corrective insole for correcting foot deformities, containing a silicone base and silicone supports, while the silicone supports are made monolithically with the silicone base and are located on its lower side, the height of each silicone support is no more than 30 mm and is calculated based on degree of deformation of the user's foot, wherein the corrective insole additionally contains a layer of leatherette located on the upper side of the silicone base, and the thickness of the silicone base and the additional layer of leatherette in total is no more than 1 mm. [RU159613, A43B 17/00, publ. 02/10/2016 Bulletin. No. 4].

A feature of the analog and prototype is that the presence of supports provides a passive massage effect of the foot due to the deformation of the supports under the pressure force generated when walking, which in turn improves blood microcirculation in the foot.

DISCLOSURE OF THE ESSENCE OF THE UTILITY MODEL

The technical result is an additional improvement in blood microcirculation in the foot.

The technical result is achieved in that the orthopedic insole contains a base having upper and lower sides, as well as supports located in rows on its lower side, and the height of each silicone support is calculated based on the degree of deformation of the user's foot, and the material from which the base and support, additionally contains glass microspheres evenly distributed in it in an amount of 5-10 g per insole.

There is an option in which the microspheres are made of potassium-sodium silicate glass, sodium borosilicate glass or soda-calcium borosilicate glass.

There is an option in which the microspheres are additionally coated with an organosilicon coating.

There is an option in which the orthopedic insole contains three rows of supports.

There is an option in which the number of supports of the first row closest to the edge of the insole is 8-14 pieces, the number of supports of the second row is 9-16 pieces, and the number of supports of the third row is 4-12 pieces.

There is an option in which the height of the supports of the first row closest to the edge of the insole is 17-35 mm, the height of the supports of the second and third row is 17-30 mm.

There is an option in which the supports of the first row closest to the edge of the insole are made in the shape of a truncated pyramid with bases in the form of a quadrangle, and the length of the larger side of the lower base is 20-25 mm, and the length of the larger side of the upper base is 15-20 mm, while the supports oriented in such a way that the lower base of the truncated pyramid is located at the base of the insole.

There is an option in which the supports of the second and third rows are made in the shape of a rectangular parallelepiped.

There is an option in which the length of the lower and upper base of the rectangular parallelepiped is 7-15 mm.

There is an option in which the base and supports are made of silicone.

There is an option in which the supports are made monolithically with the base.

There is an option in which there is an additional layer of artificial leather on the upper side of the base.

BRIEF DESCRIPTION OF THE DRAWINGS

In fig. Figure 1 schematically shows an orthopedic insole (bottom view).

In fig. Figure 2 schematically shows an orthopedic insole (side view).

In fig. Figure 3 schematically shows an orthopedic insole (isometric view).

Orthopedic insole 1 (Fig. 1) contains a base 2 (Fig. 1, Fig. 2, Fig. 3) and supports located in rows on its lower side. The material from which the base 2 and supports are made contains glass microspheres 3 evenly distributed in it (Fig. 1).

In particular embodiments of the utility model, the insole 1 contains three rows of supports, and the supports 4 (Fig. 1, Fig. 2, Fig. 3) of the first row closest to the edge of the insole are made in the shape of a truncated pyramid with bases in the form of a quadrangle, and the length of the longer side the lower base 5 (Fig. 2) is greater than the length of the larger side of the upper base 6 (Fig. 2), and are oriented in such a way that the base 5 of the truncated pyramid is located at the base 2 of the insole 1. The supports 7 (Fig. 1, Fig. 2, Fig. 3) of the second row and supports 8 (Fig. 1, Fig. 2, Fig. 3) of the third row are made in the shape of a rectangular parallelepiped.

In a particular embodiment of the utility model, on the upper side of the base 2 there is an additional layer 9 (Fig. 3) made of artificial leather.

IMPLEMENTATION OF THE UTILITY MODEL

The utility model is illustrated by the following implementation examples.

Example 1. An orthopedic insole contains a base and three rows of supports, made monolithically with the base and located on its lower side. The base of the insole and the supports are made of silicone, with a density of 1.1-1.3 g/cm ³ , preferably 1.15 g/cm ³ , into which microspheres of potassium-sodium silicate glass with an organosilicon coating in an amount of 5 are pre-introduced and evenly distributed g per one insole.

The number of supports of the first row is 8 pieces, the number of supports of the second row is 9 pieces, and the number of supports of the third row is 4 pieces. The height of the supports of the first, second and third rows is 17 mm. The length of the lower base of the truncated pyramid is 20 mm, and the length of the upper base of the truncated pyramid is 15 mm. The supports of the second and third rows are made in the shape of a rectangular parallelepiped. The length of the lower and upper base of the rectangular parallelepiped is 7 mm.

Example 2. An orthopedic insole contains a base and three rows of supports located on its lower side. The base of the insole and the supports are made of silicone, with a density of 1.1-1.3 g/cm ³ , preferably 1.2 g/cm ³ , into which microspheres of sodium borosilicate glass are pre-introduced and evenly distributed in an amount of 7 g per insole.

The number of supports of the first row is 10 pieces, the number of supports of the second row is 14 pieces, and the number of supports of the third row is 7 pieces. The height of the supports of the first row is 25 mm, the height of the supports of the second and third row is 20 mm. The length of the lower base of the truncated pyramid is 23 mm, and the length of the upper base of the truncated pyramid is 18 mm. The supports of the second and third rows are made in the shape of a rectangular parallelepiped. The length of the lower and upper base of the rectangular parallelepiped is 12 mm.

On the upper side of the base there is an additional layer made of elasto-artificial leather-T [http://www.iskoj.ru/index.php/produktsiya/iskust-koji-2?id=60].

Example 3. An orthopedic insole contains a base and three rows of supports, made monolithically with the base and located on its lower side. The base of the insole and the supports are made of silicone, with a density of 1.1-1.3 g/cm ³ , preferably 1.18 g/cm ³ , into which microspheres of sodium calcium borosilicate glass are pre-introduced and evenly distributed in an amount of 10 g per insole.

The number of supports of the first row is 14 pieces, the number of supports of the second row is 16 pieces, and the number of supports of the third row is 12 pieces. The height of the supports of the first row is 35 mm, the height of the supports of the second and third row is 30 mm. The length of the lower base of the truncated pyramid is 25 mm, and the length of the upper base of the truncated pyramid is 20 mm. The supports of the second and third rows are made in the form of a rectangular parallelepiped. The length of the lower and upper base of the rectangular parallelepiped is 15 mm.

On the upper side of the base there is an additional layer made of elasto-artificial leather-T [http://www.iskoj.ru/index.php/produktsiya/iskust-koji-2?id=60].

Before using an orthopedic insole, depending on the degree of deformation of the user’s foot, the insole is adjusted to the specific deformed foot of the user by cutting the supports, after which the insole is placed inside the shoe.

During operation, the main work of the orthopedic insole occurs during the support phase of the entire foot. In this case, supports located under the deformed arch of the foot limit its fall into the foot, ensuring its passive retention. Thus, the step is leveled, and in addition, a passive foot massage is performed due to the deformation of the supports under pressure.

A feature of the glass microspheres that make up the material from which the bases and supports are made is their low thermal conductivity and ability to reflect infrared radiation.

Thermal conductivity is the ability of material bodies to conduct energy (heat) from more heated parts of the body to less heated parts of the body through the chaotic movement of body particles. Quantitatively, the ability of a substance to conduct heat is characterized by its thermal conductivity coefficient. This characteristic is equal to the amount of heat passing through a homogeneous sample of material of unit length and unit area per unit time at a unit temperature difference (1 K). In the International System of Units (SI), the unit for thermal conductivity is W/(m⋅K). Due to the fact that glass microspheres are hollow ideal spheres with a small contact area with each other (they touch only at one point), this limits the transfer of heat between the layers of the substance.

It is well known that the human body produces thermal energy emitted in the form of infrared rays in the range of 3-50 microns with a peak at 9.6 microns. Accordingly, when the body is exposed to infrared energy with a wavelength of 9.6 microns, the body actively absorbs external energy (the so-called resonant absorption). In the case of implementing a utility model, the source of infrared radiation is the human foot.

The formation of heat that occurs when the energy of infrared radiation is absorbed leads to a local increase in the temperature of the irradiated skin by 1-2°C and causes local thermoregulatory reactions of the superficial vascular network. The vascular reaction is expressed in a short-term spasm of blood vessels (up to 30 s), and then an increase in local blood flow and an increase in the volume of blood circulating in the tissues.

The presence of microspheres also significantly changes the reflective properties of the surface of the base and supports, ensuring the scattering of incident radiation in a narrow solid angle, the axis of which is directed towards the emitting source.

Thus, the filler ensures the preservation and reflection of infrared radiation, which is the most physiological for it and ensures improved blood microcirculation in the foot.

The introduction of glass microspheres into the material from which the base and supports are made, in an amount of less than 5 g per insole, does not allow the formation of reflected infrared radiation, the energy of which, when absorbed, is sufficient to ensure heating of the skin and, as a result, there is no increase in the volume of blood circulating in the tissues .

The introduction of glass microspheres into the material from which the base and supports are made, in an amount of more than 10 g per insole, leads to an increase in its viscosity, which in turn complicates the manufacture of the insole by casting, as well as the adjustment of the insole to a specific deformed foot of the user, and in addition In addition, the cost of manufacturing the insole increases.

The use of a material containing microspheres with an organosilicon coating in a particular embodiment of the utility model leads to an increased content of alkaline components in the glass composition and ensures the sterility of the air passing through them. This is achieved by the formation of an alkaline environment when human sweat gets on the insole during its operation, and such an environment is destructive for microorganisms. In the absence of secretions, microorganisms die in the microsphere environment due to increased dryness.

Making the supports monolithic with the base in a particular embodiment of the utility model makes it possible to produce a homogeneous orthopedic insole without interfacing individual parts, which further increases its wear resistance.

The use of an additional layer of artificial leather in a particular embodiment of the utility model is due to the fabric structure of this material. As a result of the penetration of silicone into the fabric structure, it hardens and is firmly fixed to it, eliminating the possibility of tearing off the additional layer. In addition, the additional layer prevents silicone from penetrating through it onto the surface of the insole, and also gives the insole an aesthetic appearance.

Claims (10)

1. An orthopedic insole containing a base having upper and lower sides, as well as silicone supports arranged in rows on its lower side, wherein the insole is designed to fit the user’s deformed foot by cutting the supports, characterized in that the material from which the base and supports are made, contains glass microspheres in an amount of 5-10 g evenly distributed in it, while the microspheres are covered with an organosilicon coating and a layer of artificial leather is located on the upper side of the base. 2. The insole according to claim 1, characterized in that the microspheres are made of potassium-sodium silicate glass, sodium borosilicate glass or sodium calcium borosilicate glass. 3. The insole according to claim 1, characterized in that it contains three rows of supports. 4. The insole according to claim 3, characterized in that the number of supports of the first row closest to the edge of the insole is 8-14 pieces, the number of supports of the second row is 9-16 pieces, and the number of supports of the third row is 4-12 pieces. 5. The insole according to claim 3, characterized in that the height of the supports of the first row closest to the edge of the insole is 17-35 mm, the height of the supports of the second and third row is 17-30 mm. 6. The insole according to claim 3, characterized in that the supports of the first row closest to the edge of the insole are made in the form of a truncated pyramid with bases in the form of a quadrangle, and the length of the larger side of the lower base is 20-25 mm, and the length of the larger side of the upper base is 15 -20 mm, while the supports are oriented in such a way that the lower base of the truncated pyramid is located at the base of the insole. 7. The insole according to claim 3, characterized in that the supports of the second and third rows are made in the shape of a rectangular parallelepiped. 8. The insole according to claim 7, characterized in that the length of the lower and upper base of the rectangular parallelepiped is 7-15 mm. 9. Insole according to any one of paragraphs. 1-8, characterized in that the base is made of silicone. 10. Insole according to claim 9, characterized in that the supports are made monolithically with the base.