RU232093U1 - CORRECTIVE INSOLE - Google Patents

Abstract

The utility model relates to the field of massage device technology, namely to a type of massage and hygienic shoe insole. The said technical result is achieved in that the corrective insole comprises a base of variable thickness, including a front part, a middle part and a back part, on the upper side of the base there are massage points of a rounded convex shape, and on the lower side there are recesses with through holes in the base and built-in magnets, characterized in that the middle part on the upper side is located above the front part and is made with a transition to the front part with a bending radius equal to 24.5-34.5 mm, wherein the middle part is divided into a first zone with a side and a second zone with a side, the first zone of the middle part is located below the second zone with a smooth transition between them, the side of the first zone of the middle part is made with a bending radius to the first zone equal to 12.4-72 mm, and the side of the second zone of the middle part is made with a bending radius to the second zone equal to 7.5-91.8 mm, the base also includes a back part with sides, located on the upper side below the middle part and passing into the middle. part at an obtuse angle to it. The technical result of the claimed utility model consists in improving the distribution of pressure exerted on the foot. 9 s.p. f-ly, 5 ill.

Description

The utility model relates to the field of massage device technology, namely to a type of massage and hygienic shoe insole.

A VENTILATED MAGNETOTHERAPEUTIC MASSAGE INSOLE is known from the prior art [CN203884847U, published 22.10.2014], comprising an insole body and several acupuncture magnets, characterized in that the middle part of the insole body is a convex part, and the convex part corresponds to the arch of a person's foot, and several acupuncture magnets include a Yongquan point magnet, a lung orifice magnet, a liver orifice magnet, a stomach orifice magnet, a kidney point magnet, two intestinal and genital cavity magnets, wherein the Yongquan acupuncture magnet, the lung acupuncture magnet, the liver acupuncture magnet, the stomach acupuncture magnet, the kidney acupuncture magnet, two intestinal acupuncture magnets and the genital magnet, respectively, and are fixedly located in the insole so as to correspond to the acupuncture points of the foot; the insole body is respectively provided with several ventilated holes; the lower ends of the ventilated holes are located on the lower end surfaces of the insole body and respectively provided with a plurality of air guiding grooves. The ventilated magnetotherapy massage insole has the advantages that a plurality of acupuncture magnets are located on the insole body and can be used to perform magnetic therapy on the feet to effectively condition and improve the microcirculatory system of the human body.

The disadvantage of the analogue is the transitions between the front and middle parts of the insole, between the middle and back parts and between the two zones of the middle part located across the insole, which do not provide a smooth transition that would avoid abrupt changes in height and rigidity, thereby reducing the uniform distribution of pressure over the entire surface of the foot, which increases the risk of point loads, which reduces the uniformity of the distribution of pressure exerted on the foot.

Also known is an INSOLE WITH A MASSAGE FUNCTION [CN218245941U, published 10.01.2023], comprising an insole body that is adapted to the shape of the sole; the insole body comprises a front sole massage zone adapted to the shape of the front sole, a rear heel massage zone adapted to the back heel, and a middle massage zone; a flexible zone for relieving aching pain of the user's sole is located between the front sole massage zone and the middle massage zone; the flexible zone is provided with a stepped elliptical groove that penetrates through the insole body; the upper part of the elliptical groove is covered with flexible fabric; the stepped elliptical block is clamped in the elliptical groove; an installation groove is formed in the oval block; the air cushion is detachably connected in the installation groove; a plurality of hemispherical massage blocks facing the soles are located in the front sole massage zone, the back heel massage zone and the middle massage zone; in the front sole massage zone and the middle massage zone there are three rows of air holes parallel to the direction of the sole; the three rows of air holes are staggered with the hemispherical massage blocks; a cylindrical tube is located on the stepped surface of the elliptical block; the magnet is detachably connected to the cylindrical tube.

The disadvantage of the analogue is the transitions between the front and middle parts of the insole, between the middle and back parts and between the two zones of the middle part located across the insole, which do not provide a smooth transition that would avoid abrupt changes in height and rigidity, thereby reducing the uniform distribution of pressure over the entire surface of the foot, which increases the risk of point loads, which reduces the uniformity of the distribution of pressure exerted on the foot.

The closest in technical essence is the MASSAGE INSOLE [CN206423639U, published 08/22/2017], which includes a main part of a shoe last, the main part of the shoe last includes a structure for supporting the arch of the foot, the structure for supporting the arch of the foot includes a muscle for supporting the arch of the foot and is located in the area of the muscles for supporting the arch of the foot in several grooves of the stomata, each groove of the stomata has an air outlet, and the main body of the shoe last is inlaid with a plurality of magnetites, while around each magnetite, a plurality of holes for the magnetic field are uniformly distributed. The main body of the shoe last is made in one piece with magnetites. The upper surface of the main body of the shoe last is provided with convex massage points. The massage points include the massage point of the area reflecting the reproductive system, the massage point of the area reflecting the intestines, the massage point of the area reflecting the lower limbs, the massage point of the area reflecting the urinary system, the massage point of the area reflecting the digestive system, the massage point of the area reflecting the thyroid gland, the massage point of the reproductive system, the massage point of the area reflecting the liver and the massage point of the area reflecting the spleen. The beneficial properties of the utility model lie in many advantages, such as the design including arch support, acupressure, magnetic therapy and good air permeability, and also improve the comfort level and health of the shoe last.

The main technical problem of the prototype is the transitions between the front and middle parts of the insole, between the middle and back parts and between the two zones of the middle part located across the insole, which do not provide a smooth transition that would avoid abrupt changes in height and rigidity, thereby reducing the uniform distribution of pressure over the entire surface of the foot, which increases the risk of point loads, which reduces the uniformity of the distribution of pressure exerted on the foot.

The purpose of a utility model is to eliminate the shortcomings of the prototype.

The technical result of the claimed utility model consists in increasing the uniformity of the distribution of pressure exerted on the foot by the corrective insole.

The said technical result is achieved in that the corrective insole comprises a base of variable thickness, including a front part, a middle part and a back part, on the upper side of the base there are massage points of a rounded convex shape, and on the lower side there are recesses with through holes in the base and built-in magnets, characterized in that the middle part on the upper side is located above the front part and is made with a transition to the front part with a bending radius equal to 24.5 - 34.5 mm, wherein the middle part is divided into a first zone with a side and a second zone with a side, the first zone of the middle part is located below the second zone with a smooth transition between them, the side of the first zone of the middle part is made with a bending radius to the first zone equal to 12.4 - 72 mm, and the side of the second zone of the middle part is made with a bending radius to the second zone equal to 7.5 - 91.8 mm, the base also includes a back part with sides, located on the upper side below the middle part and passing into the middle. part at an obtuse angle to it.

In particular, the base is made of a single layer.

In particular, the recesses are made in a quadrangular shape.

In particular, on the lower side of the base between the front and middle parts of the base there are four recesses, two of which are made with a larger area, and the other two with a smaller area, wherein two recesses with a larger area are located along the edges of the base, and two recesses with a smaller area are located along the base between the large recesses.

In particular, on the underside of the base between the middle and back parts, three recesses are located in sequence, oriented across the base.

In particular, each recess contains 1 to 3 holes.

In particular, the magnets are made of neodymium.

In particular, there are 2-4 holes made in the base on the bottom side above each magnet.

In particular, the massage points are located in the middle and back parts and are 4-6 mm long, 2-3 mm wide and 0.1-1.1 mm high.

In particular, the base contains tourmaline powder.

Brief description of the drawings:

Fig. 1 shows a bottom view of the corrective insole.

Fig. 2 shows a top view of the corrective insole.

Fig. 3 shows the right view of the corrective insole.

Fig. 4 shows the rear view of the corrective insole.

Fig. 5 shows a front view of the corrective insole.

The figures indicate: 1 - base, 2 - front part, 3 - middle part, 4 - back part, 5 - massage points, 6 - depressions, 7 - through holes, 8 - magnets, 9 - transition to the front part, 10 - first zone, 11 - side of the first zone, 12 - second zone, 13 - side of the second zone.

Implementation of a utility model.

According to the utility model, the corrective insole (Fig. 1 - 5) comprises a base 1 of variable thickness, including a front part 2, a middle part 3 and a back part 4, on the upper side of the base there are massage points 5 of a rounded convex shape, and on the lower side there are recesses 6 with through holes 7 in the base and magnets 8 are built in, characterized in that the middle part 3 on the upper side is located above the front part 2 and is made with a transition to the front part 9 with a bending radius of the transition equal to 24.5 - 34.5 mm, wherein the middle part 3 is divided into a first zone 10 with a rim of the first zone 11 and a second zone 12 with a rim of the second zone 13, the first zone 10 of the middle part 3 is located below the second zone 12 with a smooth transition between them, the rim of the first zone 11 of the middle part 3 is made with a bending radius to the first zone 10 equal to 12.4 - 72 mm, and the side of the second zone 13 of the middle part 3 is made with a bending radius to the second zone 12 equal to 7.5 - 91.8 mm, also the base 1 includes a back part 4 with sides, located on the upper side below the middle part 3 and made with a transition to the middle part 3 at an obtuse angle to it.

The corrective insole contains a single-layer base 1 of variable thickness, consisting of a front 2, middle 3 and rear 4 parts, wherein the front 2 and rear 4 parts are made with roundings along the perimeter. The variable thickness of the base 1 in different parts of the insole allows it to be adapted to the shape of the foot, which helps to reduce overload points, ensuring uniform distribution of pressure exerted on the foot from the corrective insole.

On the upper side of the base 1 there are massage points 5 (Fig. 2) of a rounded convex shape, which are part of the base 1, which helps to improve the distribution of pressure on the foot due to the activation of reflexogenic zones, reduction of point loads, due to the improvement of blood circulation and stimulation of nerve endings. The rounded shape of the massage points helps to distribute the pressure more evenly, preventing the formation of hard pressure points. This in turn helps to reduce the risk of injury and fatigue, improving the general condition of the feet and lower limbs. All this increases the uniformity of the distribution of pressure exerted on the foot from the corrective insole.

On the lower side, in the base 1, there are recesses 6 (Fig. 4) with through holes 7. The recesses 6 reduce the contact area between the insole and the shoe, which allows the pressure to be distributed more evenly over the entire surface of the insole, thereby preventing the formation of hard pressure points on the foot. This can reduce the risk of foot pain and other problems associated with overload. The recesses 6 can act as shock absorbers, allowing the insole to deform upon contact with the shoe. This absorbs shocks and reduces the force transmitted to the foot. With each step, the recesses 6 allow the base 1 of the insole to adapt to the shape of the shoe, which reduces the load on the joints and soft tissues, thereby increasing the uniformity of the pressure distribution exerted on the foot from the corrective insole.

Through holes 7 provide air circulation under the foot, which helps to avoid excessive sweating and overheating. Reducing sweating promotes better adhesion of the foot to the insole, which reduces the likelihood of slipping and creates a more stable support. This directly affects the uniformity of pressure distribution when walking, which increases the uniformity of pressure distribution exerted on the foot from the corrective insole.

Also, magnets 8 (Fig. 1) are built into the lower side of the base 1 of the corrective insole, activating the biological zones of the foot, while they act on certain points on the foot, creating a slight pressure in these places, which improves the biomechanics of gait, blood circulation and activates reflexogenic zones, contributing to a more uniform distribution of the load over the entire surface of the foot, thereby ensuring an increase in the uniformity of the distribution of pressure exerted on the foot, from the corrective insole. In this case, magnets 8 are made of neodymium, possessing a high magnetic force with small dimensions, which allows them to provide a powerful magnetic field without increasing the thickness of the insole, which can additionally contribute to the expansion of blood vessels and improve the supply of oxygen and nutrients to the tissues of the foot, thereby can additionally increase the uniformity of the distribution of pressure exerted on the foot, from the corrective insole.

The middle part 3 is located higher than the front part 2 on the upper side and is made with a transition to the front part 9 with a bending radius of 24.5 - 34.5 mm (Fig. 3). The higher middle part 3 of the base 1 provides better support for the arch of the foot. This helps to correctly distribute the body weight, reducing pressure on the front part of the foot and preventing painful sensations in the area of the toes and metatarsal bones. The bending radius in the range of 24.5 - 34.5 mm provides a smooth transition between the middle part 2 and the front part 3. This helps to avoid abrupt changes in height and rigidity, which contributes to a more uniform distribution of pressure over the entire surface of the foot, which reduces the risk of point loads. A smooth transition to the front part 9 and support for the arch of the foot, by locating the middle part 3 above the front part 2, help reduce fatigue during long walking or standing. All this increases the uniformity of the distribution of pressure exerted on the foot from the corrective insole. When pressure is distributed evenly, it helps to avoid overload and discomfort, which is especially important for people who spend a lot of time on their feet. Also, a smooth transition to the front part of the 9 and arch support help to reduce fatigue during long walks or standing.

If the bend radius is too small (less than 24.5 mm), the transition between the middle part 3 and the forefoot 2 of the base 1 becomes too sharp, which can lead to the formation of point loads. This creates discomfort and can cause pain in the forefoot. If the bend radius is too large (more than 34.5 mm), it can lead to insufficient arch support. The corrective insole will not fix the arch correctly, which will lead to uneven weight distribution and increased pressure on the forefoot and heel. A bend radius of the transition to the forefoot 9 that is outside the range can disrupt the natural movement of the foot when walking. This leads to inefficient mechanics, increasing the load on the joints and soft tissues, which reduces the uniformity of the pressure exerted on the foot by the corrective insole.

The middle part 3 is divided into the first zone 10 with the side of the first zone 11 and the second zone 12 with the side of the second zone 13. The sides help maintain the correct position of the foot, providing stability, this allows the body weight to be evenly distributed across both zones, which reduces the risk of point loads and discomfort. When the pressure is distributed more evenly between the zones, this reduces the load on the muscles and ligaments, which allows you to stay on your feet longer without discomfort, which ultimately increases the uniformity of the pressure distribution exerted on the foot from the corrective insole.

The correct pressure distribution thanks to the collars helps prevent overuse injuries such as plantar fasciitis or heel pain. The first collar zone 11 and the second collar zone 13 provide support and stabilization, which reduces the risk of incorrect foot movement.

The first zone 10 of the middle part 3 is located below the second zone 12 with a smooth transition between them (Fig. 3), while the smooth transition takes into account the anatomical features of the foot and its arch, which contributes to the correct distribution of weight. This helps to support the arch of the foot and improves the overall distribution of pressure, reducing the risk of overloads. The smooth transition between the zones allows the muscles of the foot to work more effectively. When the pressure is distributed evenly, this reduces fatigue and discomfort, which is especially important with prolonged loads. The correct position of the zones and the smooth transition between them help maintain the natural movement of the foot. This improves the biomechanics of gait, which allows for a more effective distribution of the load with each step. All this ultimately increases the uniformity of the distribution of pressure exerted on the foot from the corrective insole.

The side of the first zone 11 of the middle part 3 is made with a bending radius to the first zone 10 equal to 12.4 - 72 mm (Fig. 5). A bending radius from 12.4 to 72 mm ensures a smooth transition between the first zone and the surrounding structures. A small radius (about 12.4 mm) allows for a more pronounced bend, which ensures a closer fit to the foot. A larger radius (up to 72 mm) contributes to a softer and more gradual transition, which helps to avoid abrupt changes in pressure. This helps to evenly distribute the load, reducing the risk of creating point loads, allowing the side to better adapt under the load, which helps absorb shock and reduce the force transmitted to the foot. This helps to reduce pressure on certain areas, especially on the heel and forefoot, which is key to preventing injuries and discomfort, thereby increasing the uniformity of the pressure distribution exerted on the foot from the corrective insole. This radius of curvature provides support for the arch of the foot, which helps distribute body weight more evenly. This reduces pressure on certain areas and promotes better balance, which is important for preventing injury and fatigue.

When the bend radius between the first zone 11 collar and the first zone 10 is less than 12.4 mm, it results in a sharp angle or bend, which can create rigid boundaries between the zone and the surrounding surface. This can lead to the formation of point loads, which increases the risk of discomfort and pain in the foot, especially in the area in contact with the collar. And a bend radius of more than 72 mm can lead to insufficient support for the arch of the foot, since the collar will not be able to effectively fix the arch in place. This can lead to uneven weight distribution, increasing pressure on the forefoot and heel, which can cause fatigue and discomfort. All this ultimately worsens the uniformity of the pressure exerted on the foot by the corrective insole.

And the side of the second zone 13 of the middle part 3 is made with a bending radius to the second zone 12 equal to 7.5 - 91.8 mm (Fig. 5). The bending radius in this range allows for precise support of the arch of the foot and allows the side of the second zone 13 to adapt to different load levels. It ensures the correct position of the foot and helps to evenly distribute the body weight, which helps to avoid pain and tension, as it is especially important with long-term use of insoles. The bending radius in this range reduces the pressure on the forefoot and heel, which reduces the likelihood of pain and fatigue. A smaller radius (7.5 mm) allows for a more pronounced bend, which improves the fit to the foot and provides support. A wider radius (91.8 mm) contributes to a softer transition, which also helps to avoid abrupt changes in pressure. This smooth load distribution reduces the risk of point loads, thereby increasing the uniformity of the pressure distribution exerted on the foot from the corrective insole.

When the bending radius between the second zone 13 collar and the second zone 12 is less than 7.5 mm, this results in a sharper angle or a rigid bend. Such sharp changes can create rigid boundaries, which causes pressure to concentrate at certain points on the foot. This leads to the formation of point loads and discomfort, especially in the arch area, thereby worsening the uniformity of the pressure distribution exerted on the foot by the corrective insole. When the bending radius is more than 91.8 mm, the second zone 13 collar may become too soft, which leads to insufficient support and cushioning. This can make the insole less effective in absorbing shock and distributing load, which increases pressure on the forefoot and heel. A bending radius outside the specified range can disrupt the natural movement of the foot. This can lead to incorrect walking positions, increasing the risk of injury and overload, since the load will be distributed unevenly, thereby worsening the uniformity of the distribution of pressure exerted on the foot by the corrective insole.

The base 1 includes the back part 4 with sides, located on the upper side below the middle part 3 and made with a transition to the middle part 3 at an obtuse angle to it. The transition of the back part 4 to the middle part 3 at an obtuse angle creates a smooth change in height, which helps to avoid abrupt changes in pressure. This contributes to a more natural distribution of the load across the entire foot and reduces the likelihood of creating point loads, which increases the uniformity of the distribution of pressure exerted on the foot from the correction insole. And the side of the back part 4 provides stability, preventing the foot from shifting inside the insole. This improves balance and even weight distribution, especially when moving, which reduces the risk of injury and fatigue. The back part 4 of the insole provides support for the arch of the foot, which is important for the correct distribution of pressure. This helps to avoid overloads in the forefoot and reduces discomfort during prolonged wear. The back part 4, made taking into account the transition at an obtuse angle, can contribute to better shock absorption. This helps reduce the force transmitted to the foot with each step and provides a more comfortable feeling. All this increases the uniformity of the pressure distribution exerted on the foot by the corrective insole.

On the upper part of the base 1, in the middle part 3 and the back part 4, there are, for example, eleven to fifteen massage points, which are made 4-6 mm long, 2-3 mm wide and 0.1-1.1 mm high, while, for example, two to eight of which are made in the upper back part 4 of the base 1 of the insole, and five to eleven massage points 5 are located in the upper middle part 3 of the base 1. Such geometric dimensions of the massage points 5 create additional diverse pressure points. This diversity allows for uniform distribution of the load on the foot, preventing the formation of point overloads and reducing discomfort. The height of the massage points (up to 1.1 mm) allows them to perform an additional shock-absorbing function. When walking, they can deform, softening impacts and reducing the force of pressure transmitted to the foot. This contributes to a more uniform distribution of the load, which ultimately can additionally increase the uniformity of the distribution of pressure exerted on the foot from the corrective insole.

Tourmaline powder is evenly mixed into the material, such as polyurethane, which the base 1 can be made of, providing anion emission. Tourmaline has the ability to generate anions (negatively charged ions) under mechanical action. When walking or moving, the tourmaline in the insole will be subject to compression and friction, which promotes the release of anions. Anions can improve air quality and have a positive effect on health, including improving blood circulation and reducing foot fatigue, it can help distribute pressure more evenly when walking, which can further improve the uniformity of the pressure distribution exerted on the foot from the corrective insole.

Examples of implementation.

First example of implementation.

The corrective insole comprises a base 1 of variable thickness, including a front part 2, a middle part 3 and a back part 4, on the upper side of the base there are massage points 5 of a rounded convex shape, and on the lower side in the base there are recesses 6 with through holes 7 and built-in magnets 8, characterized in that the middle part 3 on the upper side is located above the front part 2 and is made with a transition to the front part 9 with a transition bend radius equal to 24.5 mm, wherein the middle part 3 is divided into a first zone 10 with a side of the first zone 11 and a second zone 12 with a side of the second zone 13, the first zone 10 of the middle part 3 is located below the second zone 12 with a smooth transition between them, the side of the first zone 11 of the middle part 3 is made with a bending radius to the first zone 10 equal to 12.4 mm, and the side of the second zone 13 of the middle part 3 is made with a bending radius to the second zone 12 equal to 7.5 mm, also the base 1 includes the back part 4 with sides, located on the upper side below the middle part 3 and made with a transition to the middle part 3 at an obtuse angle to it.

Second example of implementation.

The corrective insole comprises a base 1 of variable thickness, including a front part 2, a middle part 3 and a back part 4, on the upper side of the base there are massage points 5 of a rounded convex shape, and on the lower side in the base there are recesses 6 with through holes 7 and built-in magnets 8, characterized in that the middle part 3 on the upper side is located above the front part 2 and is made with a transition to the front part 9 with a transition bend radius equal to 34.5 mm, wherein the middle part 3 is divided into a first zone 10 with a side of the first zone 11 and a second zone 12 with a side of the second zone 13, the first zone 10 of the middle part 3 is located below the second zone 12 with a smooth transition between them, the side of the first zone 11 of the middle part 3 is made with a bend radius to the first zone 10 equal to 72 mm, and the side of the second zone 13 of the middle part 3 is made with a bend radius to the second zone 12 equal to 91.8 mm, also the base 1 includes the back part 4 with sides, located on the upper side below the middle part 3 and made with a transition to the middle part 3 at an obtuse angle to it.

Third example of implementation.

The corrective insole comprises a base 1 of variable thickness, including a front part 2, a middle part 3 and a back part 4, on the upper side of the base there are massage points 5 of a rounded convex shape, and on the lower side in the base there are recesses 6 with through holes 7 and built-in magnets 8, characterized in that the middle part 3 on the upper side is located above the front part 2 and is made with a transition to the front part 9 with a transition bend radius equal to 29.5 mm, wherein the middle part 3 is divided into a first zone 10 with a side of the first zone 11 and a second zone 12 with a side of the second zone 13, the first zone 10 of the middle part 3 is located below the second zone 12 with a smooth transition between them, the side of the first zone 11 of the middle part 3 is made with a bending radius to the first zone 10 equal to 29.8 mm, and the side of the second zone 13 of the middle part 3 is made with a bending radius to the second zone 12 equal to 42.2 mm, also the base 1 includes the back part 4 with sides, located on the upper side below the middle part 3 and made with a transition to the middle part 3 at an obtuse angle to it.

Fourth example of implementation.

A corrective insole comprises a base 1 of variable thickness, including a front part 2, a middle part 3 and a back part 4, on the upper side of the base there are massage points 5 of a rounded convex shape, and on the lower side there are recesses 6 with through holes 7 in the base and magnets 8 are built in, characterized in that the middle part 3 on the upper side is located above the front part 2 and is made with a transition to the front part 9 with a transition bend radius equal to 24.5 - 34.5 mm, wherein the middle part 3 is divided into a first zone 10 with a side of the first zone 11 and a second zone 12 with a side of the second zone 13, the first zone 10 of the middle part 3 is located below the second zone 12 with a smooth transition between them, the side of the first zone 11 of the middle part 3 is made with a bend radius to the first zone 10 equal to 12.4 - 72 mm, and the side of the second zone 13 of the middle part 3 is made with a bending radius to the second zone 12 equal to 7.5 - 91.8 mm, and the base 1 also includes a rear part 4 with sides, located on the upper side below the middle part 3 and made with a transition to the middle part 3 at an obtuse angle to it.

The tests were conducted between analogues and the real device, in which 10 people used these insoles and insoles from analogues while walking on a flat surface and on stairs for 3 hours, while measuring the uniform distribution of pressure over the entire surface of the foot and point loads using stress test platform sensors and real-time pressure sensors. As a result, according to the test results of each of the insoles, it was found that the uniformity of the pressure distribution exerted on the foot is 4% higher than that of analogues.

According to the obtained data, the claimed utility model in four examples of implementation provides the greatest distribution of pressure over the entire surface of the foot and a reduction in point loads compared to the prototype and analogues, which increases the uniformity of the distribution of pressure exerted on the foot from the corrective insole.

Thus, the claimed utility model, due to the technologies applied in it, the set of characteristics and interrelations, has a positive effect on the practical use of the device and allows for an increase in the uniformity of the distribution of pressure exerted on the foot from the corrective insole.

Claims (10)

1. A corrective insole comprising a base of variable thickness including a front part, a middle part and a back part, on the upper side of the base there are massage points of a rounded convex shape, and on the lower side there are recesses with through holes in the base and built-in magnets, characterized in that the middle part on the upper side is located above the front part and is made with a transition to the front part with a bending radius equal to 24.5-34.5 mm, wherein the middle part is divided into a first zone with a side and a second zone with a side, the first zone of the middle part is located below the second zone with a smooth transition between them, the side of the first zone of the middle part is made with a bending radius to the first zone equal to 12.4-72 mm, and the side of the second zone of the middle part is made with a bending radius to the second zone equal to 7.5-91.8 mm, the base also includes a back part with sides, located on the upper side below the middle part and made with a transition to the middle part at an obtuse angle to it. 2. A corrective insole according to item 1, characterized in that the base is made in a single layer. 3. A corrective insole according to item 1, characterized in that the recesses are made in a quadrangular shape. 4. A corrective insole according to item 1, characterized in that on the lower side of the base between the front and middle parts of the base there are four recesses, two of which are made with a larger area, and the other two with a smaller area, wherein two recesses with a larger area are located along the edges of the base, and two recesses with a smaller area are located along the base between the large recesses. 5. A corrective insole according to item 1, characterized in that on the lower side of the base between the middle and back parts there are three indentations oriented across the base in succession. 6. A corrective insole according to item 1, characterized in that each recess contains 1–3 holes. 7. A corrective insole according to item 1, characterized in that the magnets are made of neodymium. 8. A corrective insole according to item 1, characterized in that 2–4 holes are made in the base on the lower side above each magnet. 9. A corrective insole according to item 1, characterized in that the massage points are located in the middle and back parts and are 4–6 mm long, 2–3 mm wide, and 0.1–1.1 mm high. 10. A corrective insole according to item 1, characterized in that the base contains tourmaline powder.