RU65377U1 - STOP ARCH CORRECTOR - Google Patents

Abstract

The utility model relates to medicine, namely to orthopedics, and is used to correct lowering of the arches of the foot and for its uniform static and functional dynamic support, as well as to eliminate painful sensations caused by biomechanical disorders in the foot. The technical result of the proposed utility model is to provide, depending on the individual characteristics of the foot, corrective efforts when walking and the uniform distribution of pressure under the arches, the individuality of the installation of the corrector, including in open shoes. The foot arch corrector consists of at least one flat base with an adhesive base coated with a protective sheath, on which a power layer is placed, on which an adaptation layer is made, forming a power protrusion having a truncated cross section through its longitudinal axis oval, the lower section of which is the boundary between the flat base and the force layer, and the upper section is the boundary between the power layer and the adaptation layer, both sections being located on one side of the longitudinal axis of the sym etria oval. The force and adaptation layers are made of polymer-crosslinked elastic-viscous material, with a Shore A hardness of 20-25 units for the force layer and with a Shore A hardness of 8-13 units for the adaptation layer.

Description

The utility model relates to the field of medicine, namely to orthopedics and is used to correct lowering (deformation) of the arch of the foot and for its uniform static and dynamic support, as well as to eliminate painful sensations caused by static disturbances and dynamic overloads.

Known insole (FR 2406434, 1979), consisting of a set of elements of various shapes, made taking into account the configuration and height at the most frequent deformations of the foot, which are set by stacking on top of each other or by nesting each other. The disadvantage of the insole is the inability to use for a delicate impact on each given link of the human biomechanical chain.

Known corrector of the transverse arch of the foot (RU 2204966, 2001), consisting of a base with a power protrusion made in the shape of an asymmetric section of an egg, a layer of glue coated with a protective coating is applied to the plane of the base. The corrector is intended only for the prevention and treatment of flattening of the transverse arch of the foot.

However, the foot normally has three main arches: transverse, external and internal longitudinal. The most important in normal biomechanics of the foot are the transverse and internal longitudinal arches. The normal arcade shape of the arches allows you to evenly distribute the load and mechanical forces in the foot. An important point in the pathogenesis of static and dynamic deformations of the foot is the violation of the shape of the arches of the foot.

The technical result of the proposed utility model is to ensure, depending on the individual characteristics of the foot,

corrective efforts when walking and uniform distribution of pressure under the arches, the individuality of the corrector installation, including in open shoes, which will lead to a decrease in specific pressure on the foot, will unload its most loaded parts, heads of the metatarsal bones and calcaneal region.

This goal is achieved by the fact that in the corrector of the arch of the foot consisting of at least one flat base with an adhesive base, covered with a protective shell on which the power layer is placed, on the last an adaptation layer is made, forming a power protrusion having a transverse, passing through its longitudinal axis, the section in the shape of a truncated oval, the lower section of which is the boundary between the flat base and the force layer, and the upper section is the boundary between the power layer and the adaptation layer, while both cross sections are They are laid on one side of the longitudinal axis of symmetry of the oval, the force and adaptation layers are made of polymer-crosslinked elastic-viscous material, with a Shore A hardness of 20-25 units for the force layer and with Shore A hardness of 8-13 units for the adaptation layer.

In addition, for the transverse arch of the foot, the power protrusion in the plan may have a drop-shaped or smoothed L-shaped.

Preferably, for the longitudinal arch of the foot, the power projection in the plan has the shape of a semicircle.

For the heel region, the power projection in the plan has the shape of a rounded rectangle on the smaller side.

In addition, the power and adaptation layers can be made of silicone.

Also, the time of reverse passive relaxation of the material of the power projection is 13-15 cm / sec for the force layer, and 4-6 cm / sec for the adaptation layer.

Figure 1 shows a cross section of the corrector.

The corrector of the arch of the foot consists of at least one flat base 1 (Fig. 1) with an adhesive base 4, covered with a protective sheath 5, on which the power layer 2 is placed, on the last an adaptation layer 3 is made, forming a power protrusion. The force layer 2, which performs the function of dynamic support and control of deformation during the movement of the functional parts of the foot due to its elastic-viscous properties of the material and shape, has a cross section passing through its longitudinal axis in the shape of an oval truncated by parallel planes, the lower section of which is the boundary between a flat base 1 and a force layer 2, and the upper section is the boundary between the power layer and the adaptation layer 3, while both sections are located on one side of the longitudinal axis of symmetry of the oval.

Depending on the static disturbance of the feet and associated symptoms, several force projections are used, with appropriate bases. For the transverse arch of the foot, the power protrusion in the plan can have a drop-shaped or smoothed L-shaped. For the longitudinal arch of the foot, the power protrusion in the plan has the shape of a semicircle, and for the heel region the power protrusion in the plan has the shape of a rounded rectangle on the smaller side.

The adaptation layer 3 makes the force layer 2 and the functional sections of the foot where the corrector is located as congruent as possible. Due to the visco-elastic properties of the material, it smooths the edges of the force layer 2 and the individual geometric shapes of the various departments of the foot.

The force and adaptation layers are made of polymer-crosslinked elastic-viscous material, for example, silicone, with a Shore A hardness of 20-25 units for the force layer and with a Shore A hardness of 8-13 units for the adaptation layer, the reverse passive relaxation time of the power protrusion material is for force layer - 13-15 cm / sec, and for the adaptation layer - 4-6 cm / sec.

The corrector is fixed in the shoe when removing the protective shell from one of the bases. The glue base allows you to rigidly fix the device in shoes and preventing its migration - to perform its main, corrective function. If necessary, the location of the power protrusions with their bases can be changed by first peeling it off.

The proposed corrector of the arch of the foot makes up for the reduced depreciation function of the foot.

Claims (6)

1. Corrector of the arch of the foot, consisting of at least one flat base with an adhesive base, covered with a protective shell, on which the power layer is located, characterized in that the adaptation layer is made on the power layer, the power layer has a transverse, passing through it the longitudinal axis, the cross-sectional shape truncated by parallel planes, an oval, the lower cross-section of which is the boundary between the flat base and the force layer, and the upper cross-section is the boundary between the power layer and the adaptation layer, both sections being enes on the one side of the longitudinal symmetry axis of the oval. 2. The corrector according to claim 1, characterized in that for the transverse arch of the foot, the power protrusion in the plan has a drop-shaped or smoothed L-shaped. 3. The corrector according to claim 1, characterized in that for the longitudinal arch of the foot, the power projection in plan has the shape of a semicircle. 4. The corrector according to claim 1, characterized in that for the heel region the power projection in plan has the shape of a rounded rectangle on the smaller side. 5. The corrector according to claim 1, characterized in that the power and adaptation layers are made of silicone. 6. The corrector according to claim 1, characterized in that the reverse passive relaxation time of the material of the power projection is 13-15 cm / s for the force layer, and 4-6 cm / s for the adaptation layer.