WO2019240729A1

WO2019240729A1 - Reflexology applicator

Info

Publication number: WO2019240729A1
Application number: PCT/UA2019/000069
Authority: WO
Inventors: Николай ЛЯПКО
Original assignee: Николай ЛЯПКО
Priority date: 2018-06-14
Filing date: 2019-05-27
Publication date: 2019-12-19

Abstract

The invention relates to medicine, specifically to physiotherapy devices in the form of applicators intended for exerting an effect on reflexogenic zones of the human body. The claimed reflexology applicator comprises an elastic base in which reflex effecting means are fastened, the working elements of which protrude out of the base and form a working side of the applicator. Moreover, the reflex effecting means are conductors having bends that are disposed in at least one plane, and at least a part of said bends, functioning as working elements, protrudes out of the base on at least one side.

Description

Reflexology applicator

The invention relates to medicine, to physiotherapeutic devices, made in the form of applicators, designed for physiotherapeutic effects on the reflexogenic zones of the human body, can be used for therapeutic and preventive purposes in medical institutions and in domestic conditions.

Known applicators for reflexology, as a rule, are made in the form of an elastic base of a given spatial configuration with elements of reflex action in the form of needles, the tips of which extend beyond the base and form the working side of the applicator. In such applicators, the main factor in the reflex effect is the mechanical effect of the needles on the skin of the user, which is expressed in the deformation of the skin in the radial direction by the tips of the needles without damaging the skin (spot pricking).

Known as an analog, the applicator Lyapko N.G. (Ukrainian patent for utility model N ° 60, IPC A61 H 11/00 A61 H 39/08, filing date 06/30/1997), which is made in the form of a dielectric base of any shape, mainly rectangular, from any elastic material, mainly from rubber on which the reflex protrusions are made with the elements of reflex action fixed in them in the form of needles, the tips of which, like working elements, protrude beyond the reflex protrusions and form the working side of the applicator. The needles are made in the form of studs of different metals (with different electrochemical potentials) and are arranged with alternating needles of different metals. When the working side of the applicator is pressed against the user's body, the needle tips deform the skin in the radial direction without damaging it.

Common features of this analogue and the claimed solution are: an applicator for reflexology, including an elastic dielectric base of a given spatial configuration, in which means of reflex action are fixed, the working elements of which extend beyond the base with the formation of the working side of the applicator.

For the manufacture of such an applicator, it is necessary to manufacture individual needles, correctly place and securely fix a large number of needles in the base, which greatly complicates the manufacturing technology of the applicator.

A device for reflexology was selected as a prototype (Ukrainian patent for utility model Ns 103079, IPC A61 H 39/08, application filing date 11/14/2014). The applicator contains a dielectric elastic base of a given spatial configuration, on which reflex protrusions are made with elements of reflex action fixed in them in the form of needles, spikes which, as working elements, protrude beyond the limits of the reflex protrusions and form the working side of the applicator. The needles are made with heads, as means of fixing the needles at the base. The heads of the needles are placed and fixed in the body of the base during plastic molding and subsequent solidification of the base. The needles are made of different metals (with different electrochemical potentials) and are arranged with alternating needles of different metals. The applicator is made with the means of electrical connection of the selected groups of needles to the source of electrical signals, which makes it possible to expose the user to the body with electrical signals of various sizes and shapes, that is, expands the factors of the reflex effect of the applicator. These tools are made in the form of conductive base layers connected to a source of electrical signals in which the heads of selected groups of needles are placed.

Common features of the prototype and the claimed solution are: an applicator for reflexology, including an elastic dielectric base of a given spatial configuration, in which means of reflex action are fixed, the working elements of which extend beyond the base with the formation of the working side of the applicator.

As in the aforementioned analog, for the manufacture of such an applicator, it is necessary to manufacture separate needles, correctly place and securely fasten a large number of needles in the base when it is molded, which requires special devices and significantly complicates the manufacturing technology of the applicator.

The basis of the invention is the task of simplifying the manufacturing technology of the applicator.

The problem is solved in that in the applicator for reflexology, including an elastic dielectric base of a given spatial configuration, in which are fixed means of reflex exposure, the working elements of which extend beyond the base with the formation of the working side of the applicator, according to the invention, the means of reflex exposure are made in the form of conductors with bends at least in one plane, all or part of which, as working elements, protrude beyond the base, at least about bottom side of the base.

These signs are essential features of the invention, as they are necessary and sufficient to solve the problem - the simplification of the manufacturing technology of the applicator.

The implementation of the means of reflex action in the form of conductors with bends in at least one plane, all or part of which, as working elements, extend beyond the base, at least on one side of the base, eliminates the need for the manufacture of individual needles, proper placement and reliable fastening of a large number of needles in the base during its formation. Conductors with bends are obtained on conventional dies using well-known technologies. The location of the curved conductors in the base (longitudinal or transverse rows) when forming the base is a simple operation. The bends located in the base provide reliable fastening of the conductors in the base.

Conductors can be made in the form of a broken line, or a wavy line, or combinations of broken and wavy lines.

Conductors can be made with bends that form loops in the vertical plane.

Conductors can be made in the form of a one-way or multi-way coil spring.

Conductors can be made with bends in one plane or in two mutually perpendicular planes.

The bends of the conductors may extend beyond the base on one side of the base with the formation of one working side of the applicator, or on two opposite sides of the base with the formation of two working sides of the applicator.

Adjacent conductors are expediently made of various metals forming galvanic pairs, which upon contact with the skin of the user cause the known effects of galvanizing the skin and galvanic electrophoresis.

The base may have a flat or three-dimensional spatial configuration.

The following is a description of the inventive applicator with reference to the drawings, which show:

FIG. 1 - Applicator for reflexology, the implementation of continuous conductors in the form of broken lines, the peaks of which protrude from one side of the elastic base.

FIG. 2 - Applicator for reflexology, types A, B in FIG. 1.

FIG. 3 - Applicator for reflexology, the implementation of continuous conductors in the form of broken lines, the peaks of which protrude on both sides of the elastic base.

FIG. 4 - Applicator for reflexology, types B, D in FIG. 3.

FIG. 5 - Applicator for reflexology, the implementation of continuous conductors in the form of wavy lines, the peaks of which protrude from one side of the elastic base.

FIG. 6 - Applicator for reflexology, types D, E in FIG. 5. FIG. 7 - Applicator for reflexology, the implementation of continuous conductors in the form of wavy lines, the peaks of which protrude on both sides of the elastic base.

FIG. 8 - Applicator for reflexology, types G, K in FIG. 7.

FIG. 9 - Applicator for reflexology, the implementation of continuous conductors in the form of a combination of broken and wavy lines, the peaks of which protrude from both sides of the elastic base.

FIG. 10 - Applicator for reflexology, types L, M in FIG. 9.

FIG. 11 - Applicator for reflexology, the implementation of continuous conductors with bends forming loops.

FIG. 12 - Applicator for reflexology, the implementation of continuous conductors with bends forming loops, and with bends between the loops in the body of the elastic base.

FIG. 13 - Applicator for reflexology, types H, O and P, P in FIG. 12, 13, respectively.

FIG. 14 - Applicator for reflexology, the implementation of continuous conductors with bends, forming loops, protruding from both sides of the elastic base.

FIG. 15 - Applicator for reflexology, types C, T in FIG. 14 perform continuous conductors with bends in one (vertical) plane.

FIG. 16 - Applicator for reflexology, types C, T in FIG. 14 execution of continuous conductors with bends in two (vertical and horizontal) planes.

FIG. 17 - Applicator for reflexology, the implementation of continuous conductors in the form of a one-way coil spring, the turns of which protrude from one side of the elastic base.

FIG. 18 - Applicator for reflexology, types U, F in FIG. 17.

FIG. 19 - Applicator for reflexology, the implementation of continuous conductors in the form of a one-way coil spring, the turns of which protrude from both sides of the elastic base.

FIG. 20 - Applicator for reflexology, types X, C in FIG. 19.

FIG. 21 - Applicator for reflexology, the implementation of continuous conductors in the form of a two-way coil spring, the turns of which protrude from both sides of the elastic base.

FIG. 22 - Applicator for reflexology, types H, W in FIG. 21.

FIG. 23 - Applicator for reflexology, the implementation of the spring with a circular cross section. FIG. 24 - Applicator for reflexology, the implementation of the spring with a figured (four-pointed star) cross-section.

FIG. 25 - Applicator for reflexology, the implementation of the elastic base in the form of a rectangle.

FIG. 26 - Applicator for reflexology, the execution of an elastic base in the form of a tape.

FIG. 27 - Applicator for reflexology, execution of an elastic base in the form of petals.

FIG. 28 - Applicator for reflexology, the implementation of an elastic base in the form of a shoe insole.

FIG. 29 - Applicator for reflexology, the implementation of an elastic base in the form of a cylinder.

FIG. 30 - Applicator for reflexology, incision SH-SH in FIG. 29.

FIG. 31 - Applicator for reflexology, the implementation of an elastic base in the form of a sphere.

FIG. 32 - Applicator for reflexology, an example of the use of a cylindrical elastic base in a roller massager.

The applicator for reflexology includes an elastic dielectric base of a given spatial configuration, in which means of reflex action are fixed, the working elements of which extend beyond the base with the formation of the working side of the applicator. Means of reflex exposure are made in the form of conductors with bends in at least one plane. All or part of the bends of the conductors protrude beyond the base as working elements.

The bends of the conductors can have different designs (different shapes), which determines the features of the reflex effect of bends, as work elements, on the user's body.

In FIG. 1, 2 shows an example of an applicator, in the base 1 of which conductors 2 are fixed, made in the form of a broken line, the pointed peaks 3 of which extend beyond the base 1 on one side, forming one working side of the applicator. Neighboring conductors 2 can be connected to opposite poles of electrical signal sources. The reflex effect of such an applicator is determined by the mechanical effect of the pointed peaks 3 and the effect of electrical signals on the user's body.

In FIG. 3, 4, an example of a similar applicator is shown in which the pointed tops 3 of the conductors 2 protrude beyond the base 1 from opposite sides of the base, forming two working sides of the applicator. The reflex effect of such the applicator is also determined by the mechanical action of the pointed peaks 3 and the impact of electrical signals on the user's body.

In FIG. 5, 6 shows an example of an applicator, in the base 1 of which conductors 4 are fixed, made in the form of a wavy line, the rounded peaks 5 of which extend beyond the base 1 on one side, forming one working side of the applicator. Neighboring conductors 4 can be connected to opposite poles of electrical signal sources. The reflex effect of such an applicator is determined by the mechanical effect of the rounded peaks 5 and the effect of electrical signals on the user's body.

In FIG. 7, 8, an example of a similar applicator is shown in which the rounded vertices 5 of the conductors 4 extend beyond the base 1 from opposite sides of the base, forming two working sides of the applicator. The reflex effect of such an applicator is also determined by the mechanical effect of the rounded peaks 5 and the effect of electrical signals on the user's body.

In FIG. 9, 10 shows an example of an applicator, in the base 1 of which conductors 6 are fixed, made in the form of a combination of broken and wavy lines. The pointed peaks 7 of the broken line extend beyond the base 1 on one side, and the rounded peaks 6 of the wavy line on the other, opposite side of the base 1. Thus, two working sides of the applicator with different characteristics of mechanical impact on the user's body are obtained. Neighboring conductors 6 can be connected to the opposite poles of the sources of electrical signals. The reflex effect of such an applicator is determined by the mechanical effect of the pointed peaks 7 or rounded peaks 8 and the effect of electrical signals on the user's body.

In FIG. 11-13, an example of an applicator embodiment is shown, in the base 1 of which conductors 9 are fixed, made with bends forming loops 10 of the top 11 of which extend beyond the base 1 on one side. Neighboring conductors 9 can be connected to opposite poles of electrical signal sources. The reflex effect of such an applicator is determined by the mechanical effect of the peaks 11 and the effect of electrical signals on the user's body. Conductors 9 can be made with additional bends 12 in the areas between the loops 10 (Fig, 12). Bends 12 provide elastic properties of the base 1 and prevent damage (tears) of the conductors 9 during deformation of the base 1. In FIG. 14-16 show an example of the applicator, in the base 1 of which are mounted conductors 13 made with bends that form in the vertical plane oppositely directed loops 14, 15, peaks 16, 17 of which extend beyond the base 1 from opposite sides, forming two working sides applicator. Conductors 13 can be made with additional bends 18 in the horizontal plane (Fig, 16). Neighboring conductors 13 can be connected to opposite poles of electrical signal sources. The reflex effect of such an applicator is determined by the mechanical effect of the peaks 16 or peaks 17 and the impact of electrical signals on the user's body.

In FIG. 17, 18 shows an exemplary embodiment of an applicator, in the base 1 of which conductors 19 are fixed, made in the form of a one-way coil spring. The vertices 20 of the coil of spring protrude beyond the base 1 from one side, forming one working side of the applicator. Neighboring conductors 19 can be connected to opposite poles of electrical signal sources. The reflex effect of such an applicator is determined by the mechanical effect of the vertices 20 and the effect of electrical signals on the user's body.

In FIG. 19, 20 shows an example of a similar applicator, in which the vertices 20 of the spring turns protrude beyond the base 1 from two opposite sides, forming two working sides of the applicator.

In FIG. 21, 22 shows an example of an applicator, in the base 1 of which conductors 21, 22 are made, made in the form of a two-way coil spring. The vertices 23 of the turns of the two-way spring protrude beyond the base 1 from two sides, forming two working sides of the applicator. Conductors 21, 22 can be connected to opposite poles of electrical signal sources. The reflex effect of such an applicator is determined by the mechanical action of the peaks 23 and the effect of electrical signals on the user's body.

All or part of the above springs can be made with a circular cross section (Fig. 23) or with a figured (four-pointed star 24) cross section (Fig. 24).

Neighboring conductors 2, 4, 6, 9, 13, 19, 21, 22 are expediently made of different metals forming galvanic pairs, which, when in contact with the skin of the user, cause the known effects of galvanizing the skin and galvanic electrophoresis The base 1 of the applicator can have a flat spatial configuration, for example, can be made in the form of a rectangle 25 (Fig. 25), in the form of a tape 26 (Fig. 26), in the form of petals 27 (Fig. 27), in the form of a shoe insole 28 ( Fig. 28).

The base 1 of the applicator may have a three-dimensional spatial configuration, for example, in the form of a cylinder 29 (Fig. 29, 30) or a sphere 30 (Fig. 31).

The cylindrical base 29 can be used as the working fluid of the roller massager 31 (Fig. 32).

Claims

Claim

1. The applicator for reflexology, comprising an elastic dielectric base (1) of a given spatial configuration in which means of reflex exposure are fixed, the working elements of which extend beyond the base (1) with the formation of the working side of the applicator, characterized in that the means of reflex exposure are made in the form conductors (2) with bends in at least one plane, all or part of which, as working elements (3), extend beyond the base (1) of at least one side of the base (1).

2. The applicator according to claim 1, characterized in that the conductors are made in the form of a broken line (2), or a wavy line (4), or combinations of broken and wavy lines (6).

3. The applicator according to claim 1, characterized in that the conductors are made with bends forming loops (10) in a vertical plane.

4. The applicator according to claim 1, characterized in that the conductors are made in the form of a one-way (19) or multi-way coil spring (21, 22).

5. The applicator according to claim 1, characterized in that the conductors are made with bends in one plane or in two mutually perpendicular planes.

6. The applicator according to claim 1, characterized in that the bends of the conductors extend beyond the base (1) on one side of the base (1) to form one working side of the applicator, or on two opposite sides of the base (1) to form two working sides of the applicator .

7. The applicator according to claim 1, characterized in that the adjacent conductors are made of different metals.

8. The applicator according to claim 1, characterized in that the base (1) has a flat or three-dimensional spatial configuration.