WO2019240727A1

WO2019240727A1 - Reflexology applicator

Info

Publication number: WO2019240727A1
Application number: PCT/UA2019/000065
Authority: WO
Inventors: Николай ЛЯПКО
Original assignee: Николай ЛЯПКО
Priority date: 2018-06-14
Filing date: 2019-05-27
Publication date: 2019-12-19
Also published as: RU2734131C2; RU2019101333A; RU2019101333A3

Abstract

The invention relates to medicine, specifically to physiotherapy devices in the form of needle applicators intended for exerting an effect on reflexogenic zones of the human body. The claimed reflexology applicator comprises an elastic base and needles, the bases of which are fastened in the applicator base such that the points of the needles protrude out of the applicator base, and are provided with metal coatings. Moreover, nonmetal layers are provided between the metal coatings and the bases of the needles, and the applicator is provided with means for electrically connecting the needle bases and the metal coatings to electrical signal sources.

Description

Reflexology applicator

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

Widely known are applicators, including an elastic base of the applicator, needles that are fixed to the base of the applicator so that the tips of the needles protrude beyond the base of the applicator to form the working side of the applicator.

Thus, an applicator is known that includes an elastic base of the applicator, needles that are fixed to the base of the applicator so that the tips of the needles protrude beyond the base of the applicator to form the working side of the applicator. The needles are made in the form of rods (studs) with a pointed end and a head on the other end, as a means of fixing the needle at the base of the applicator. The needles are made of materials (metals) with different electrochemical potentials. The needles can be made with metal coatings, the electrochemical potential of which differs from the electrochemical potential of the needle material. With the indicated execution of needles between the needles, between the coatings of the needles, between the needles and their coatings, galvanic microcurrents occur that cause the skin galvanizing effect, as well as galvanic electrophoresis, the result of which is the transfer of trace elements (needle materials and their coatings) into the user's body. These factors determine the therapeutic effect of the applicator on the user's body (Ukrainian patent for utility model N ° 53553, IPC A61 H 39/08, filing date 04/13/2010)

Common features of the analogue and the claimed solution are: an applicator for reflexology, including the base of the applicator of a given spatial configuration and needles, the bases of which are fixed in the base of the applicator with the possibility of the tips of the needles protruding beyond the base of the applicator and are made with metal coatings.

The therapeutic effect of such an applicator is limited by the mechanical action of the tips of the needles, the effect of galvanic microcurrents and galvanic electrophoresis on the user's body.

As a prototype, an applicator for reflexology was selected, known according to the patent of the Russian Federation RU2195917, IPC A61 H 39/08, priority date 07.15.1999 (also published: WO0105351 (A2), US8025673 (B1), PL198239 (B1), MXRA02000523 (A) , LV12858 (B) LT2002006 (A), IL147656 (A), HU0202773 (A2), GB2368530 (A), FI20020072 (A), ES2204337 (A1), EA200200159 (A1), DE10085044 (T1), CA2381217 (A1), BG106308 (A), AU7328300 (A).

The applicator contains the base of the applicator with the needles fixed in it. The tips of the needles protrude beyond the base, forming the working side of the applicator. Each needle contains the base of the needle, made in the form of a rod, one end of which is pointed (the tip of the needle), and the head (thickening) is made on the other end, which is a means of fixing the needle at the base of the applicator. The basics of the needles are made of at least a single-layer coating with the formation near the needle tip of zones of at least two materials with different electrochemical potentials. Various coatings are possible. The coating can be applied to the needle base with the needle tip exposed, or applied to the needle tip with the needle base exposed, or it can be made of several layers of different materials with the needle tip exposed and each coating layer near the tip. The bases and coatings of needles can be made of metals selected from the group including: steel, copper, chromium, nickel silver, cobalt, aluminum, magnesium, zinc, tin, titanium, vanadium, beryllium, gold, platinum, palladium, strontium, tellurium, as well as their alloys and oxides. The needles located nearby are made of different materials. With this embodiment of needles, galvanic microcurrents occur between the needles and between the bases of the individual needles and their coatings in the epidermis of the user's skin, resulting in a well-known effect of galvanizing the skin. In addition, as a result of galvanic electrophoresis, many trace elements are transferred to the user's body. These phenomena enhance the therapeutic effect of the applicator.

Common features of the prototype and the claimed solution are: an applicator for reflexology, including the base of the applicator of a given spatial configuration and needles, the bases of which are fixed in the base of the applicator with the possibility of the tips of the needles protruding beyond the base of the applicator and are made with metal coatings.

The therapeutic effect of such an applicator is limited by three factors of therapeutic effect - mechanical action on the skin with the tips of the needles, exposure to galvanic microcurrents (galvanization of the skin), transfer of microelements to the user's body as a result of galvanic electrophoresis.

The basis of the invention is the task of increasing the efficiency of the applicator by expanding the factors of therapeutic effects on the user's body.

The problem is solved in that in the applicator for reflexology, containing the elastic base of the applicator for a given spatial configurations and needles, the bases of which are fixed in the base of the applicator with the possibility of the tips of the needles protruding beyond the base of the applicator and are made with metal coatings, according to the invention, layers of non-metal are made between the metal coatings and the bases of the needles, while the applicator is made with means for electrically connecting the bases of the needles and metal coating of needles with sources of electrical signals.

These signs are essential features of the invention, since in their totality are necessary and sufficient to achieve a technical result - the expansion of the factors of therapeutic effects on the user's body.

The implementation of needles with a metal coating isolated from the base of the needle with a layer of non-metal, as well as the implementation of the applicator with means for electrically connecting the bases of the needles and their metal coatings with sources of electrical signals, allows you to get a system of bipolar needle electrodes, which allows you to act on the user's body with electrical signals of a given value and forms separately to selected groups of needle electrodes or to each needle electrode, providing additional factors for the therapeutic effect of apple Kator - the impact of electrical signals of various sizes and shapes on selected parts of the user's body (in addition to the mechanical effect, the effects of galvanic microcurrents and electrophoresis - according to the prototype). All of the above increases the efficiency of the applicator. In addition, the applicator can be used as a diagnostic device, with which it is possible to scan both individual sections and individual points on the patient’s body, determining their electrical parameters, which extends the applicator’s functionality.

A non-metal can be either a dielectric, or a semiconductor, or a material having the properties of an inverse piezoelectric effect, or a material with high ohmic resistance. The choice of non-metal material further expands the factors of the therapeutic effect of the applicator - exposure to infrared or ultraviolet radiation (when using a semiconductor material), needle vibration (when using a material having the properties of the inverse piezoelectric effect), thermal effect (when using a material with high ohmic resistance). The ability to select non-metal materials, as well as schemes for connecting needles to sources of electrical signals, provides a variety of therapeutic effects, the choice of therapeutic effects, as well as their combinations, depending on the purpose of reflexology. The base of the needles can be made in the form of a rod with at least one tip, while the means for fixing the needles in the base of the applicator can be made in the form of at least one shoulder on the rod, or in the form of a threaded section on the rod, or the form of discs on the rods, or combinations thereof.

The base of the needles can be made in the form of a plate with at least one point on at least one of the sides of the plate, and this plate is a means of fixing the needle in the base of the applicator.

The base of the needles can be made of wire with at least one bend in the horizontal and / or vertical plane, with the end sections of the wire made in the form of needle tips, and the middle portion of the wire is a means of fixing the needle at the base of the applicator.

These options for the implementation of the basics of needles are technical equivalents within the essence of the proposed solution.

Means for electrical connection of needles with sources of electrical signals can be made in the form of insulated conductive layers of the base of the applicator in contact with the base of the needles or with metal coatings of the needles.

The needles can be made with at least two tips protruding beyond the base of the applicator on opposite sides of the base with the formation of two working sides of the applicator. This solution allows you to expand the functionality of the applicator when performing opposite working sides of the applicator with different factors of therapeutic effect.

Permanent magnets or solenoids connected to a source of electrical signals can be mounted on the bases of the needles. Permanent magnets act on the body with a constant magnetic field, solenoids can be used as electromagnets or as inductors to heat the base of the needles and heat the body of the user.

The base of the applicator may have a flat spatial configuration made in the form of a rectangular sheet, or ribbon, or petals, or a shoe insole or other flat shapes.

The base of the applicator may have a three-dimensional spatial configuration, made in the form of a cylinder, or a sphere, or a hemisphere, or similar three-dimensional forms, or a combination of these three-dimensional forms.

The spatial configuration of the base of the applicator is determined by the features of the application of the applicator (rug, roller, massager, etc.), as well as the shape of the areas of the body on which the reflexology procedure is performed.

The applicator is advisable to perform with means of fixing the base of the applicator on the body of the user. The following is a description of the inventive applicator for reflexology with reference to the drawings, which show:

FIG. 1 - Applicator for reflexology, schematic diagram of the applicator.

FIG. 2 - Applicator for reflexology, view A in FIG. 1.

FIG. 3 - The applicator for reflexology, the implementation of the basis of the needle in the form of a rod, and means of fixing the needle in the base of the applicator - in the form of one annular collar on the rod.

FIG. 4 - The applicator for reflexology, the implementation of the basis of the needle in the form of a rod, and means of fixing the needle in the base of the applicator - in the form of two annular beads on the rod.

FIG. 5 - The applicator for reflexology, the implementation of the basis of the needle in the form of a rod, and means of fixing the needle in the base of the applicator - in the form of three annular beads on the rod.

FIG. 6 - The applicator for reflexology, the implementation of the basis of the needle in the form of a rod, and means of fixing the needle in the base of the applicator - in the form of a threaded section on the rod.

FIG. 7 - The applicator for reflexology, the implementation of the basis of the needle in the form of a rod, and means of fixing the needle in the base of the applicator - in the form of a threaded section with an annular collar on the rod.

FIG. 8 - The applicator for reflexology, the implementation of the basis of the needle in the form of a rod, and means of fixing the needle in the base of the applicator - in the form of disks on the rod.

FIG. 9 - Applicator for reflexology, types B1, B2, BZ, respectively in FIG. 3, 4, 5.

FIG. 10 - Applicator for reflexology, view B4 in FIG. 6.

FIG. 11 - Applicator for reflexology, view B5 in FIG. 7.

FIG. 12 - Applicator for reflexology, view B6 in FIG. 8.

FIG. 13 - Applicator for reflexology, the implementation of the basis of the needle in the form of a plate with points on one side of the plate.

FIG. 14 - Applicator for reflexology, view B in FIG. thirteen.

FIG. 15 - Applicator for reflexology, the implementation of the basis of the needle from the wire with bends in the vertical and / or horizontal planes.

FIG. 16 - Applicator for reflexology, view G in FIG. 15, performing a needle base with bends in a vertical plane.

FIG. 17 - Applicator for reflexology, view G in FIG. 15, the implementation of the basis of the needle with bends in the horizontal and vertical planes.

FIG. 18 - Applicator for reflexology, examples of needle tips. FIG. 19 - Applicator for reflexology, an example of the applicator with a three-layer base with electrically conductive outer layers, the base of the needles are made in the form of a rod with three annular collars.

FIG. 20 - Applicator for reflexology, an example of an applicator with a three-layer base with electrically conductive outer layers, the base of the needles is made in the form of a rod with a threaded section and with an annular collar.

FIG. 21 - Applicator for reflexology, an example of an applicator with a three-layer base with electrically conductive outer layers, the base of the needles is made in the form of a plate with points on one side of the plate.

FIG. 22 - Applicator for reflexology, view D in FIG. 21.

FIG. 23 - Applicator for reflexology, an example of the applicator with a three-layer base with electrically conductive outer layers, the base of the needles are made of wire with bends in the vertical and / or horizontal planes.

FIG. 24 - Applicator for reflexology, view E in FIG. 23, the base of the needle is made with bends in a vertical plane.

FIG. 25 - Applicator for reflexology, view E in FIG. 23, the base of the needle is made with bends in the vertical and horizontal planes.

FIG. 26 - Applicator for reflexology, an example of the applicator, in which the upper electrically conductive layer is made in the form of electrically isolated from each other sections in contact with metal coatings of a given group of needles.

FIG. 27 - Applicator for reflexology, view G in FIG. 26.

FIG. 28 - Applicator for reflexology, an example of the applicator, in which the upper and lower electrically conductive layers are made in the form of electrically isolated from each other sections in contact with metal coatings or with the bases of the needles.

FIG. 29 - Applicator for reflexology, section KK of FIG. 28.

FIG. 30 - Applicator for reflexology, view L in FIG. 28.

FIG. 31 - Applicator for reflexology, view M in FIG. 28.

FIG. 32 - Applicator for reflexology, an example of the applicator, in which the needle is made with two tips protruding beyond the base of the applicator on opposite sides of the base of the applicator.

FIG. 33 - Applicator for reflexology, an example of the implementation of the applicator with permanent magnets.

FIG. 34 - Applicator for reflexology, an example of the applicator with solenoids. FIG. 35 - Applicator for reflexology, an example of the applicator with built-in power supply to the applicator base, an electric signal generator and a switch.

FIG. 36 - Applicator for reflexology, performing the base of the applicator in the form of a tape.

FIG. 37 - Applicator for reflexology, performing the base of the applicator in the form of petals.

FIG. 38 - Applicator for reflexology, performing the applicator base in the form of a shoe insole.

FIG. 39 - Applicator for reflexology, performing the base of the applicator in the form of a cylinder.

FIG. 40 - Applicator for reflexology, performing the base of the applicator in the form of a sphere.

FIG. 41 - Applicator for reflexology, performing the base of the applicator in the form of a hemisphere.

FIG. 42 - Applicator for reflexology, the use of the base of a cylindrical applicator in a cylindrical massage roller.

FIG. 43 - Applicator for reflexology, the use of the basis of a spherical applicator in a spherical massage roller.

FIG. 44 - Applicator for reflexology, the implementation of the means of fixing the base of the applicator in the form of free tapes connected to the base.

FIG. 45 - Applicator for reflexology, the implementation of the means of fixing the base of the applicator in the form of hooks connected to the base.

FIG. 46 - Applicator for reflexology, the implementation of the means of fixing the base of the applicator in the form of a double-slot buckle and a free tape connected to the base.

FIG. 47 - Applicator for reflexology, the implementation of the means of fixing the base of the applicator in the form of a belt connected to the base using slagging.

FIG. 48 - Applicator for reflexology, section H in FIG. 47.

The applicator for reflexology includes the base of the applicator, needles attached to the base of the applicator with the possibility of protrusion of the tips of the needles beyond the base of the applicator with the formation of the working side of the applicator. The needles are made with a metal coating. A feature of the applicator is that layers of non-metal are made between the metal coatings of the needles and the needles, and the applicator is made with means for electrically connecting the needles and the metal coatings of the needles with sources of electrical signals. In FIG. 1, 2, a schematic diagram of such an applicator is shown. The base 1 of the applicator is made in the form of a sheet of elastic material. At the base of the 1 applicator, the bases of 2 needles are fixed, the tips of 3 of which protrude beyond the base of the 1 applicator, forming the working side of the applicator. On the needles (on the bases of 2 needles) metal coatings 4 are made. Between the metal coatings 4 and the bases 2 of the needles layers 5 of non-metal are made. On the basis of 2 needles, means for fixing the needles in the base of the 1 applicator are made in the form of three beads 6. The applicator is made with means 7 for the electrical connection of the metal coatings of 4 needles with sources of electrical signals and means 8 for the electrical connection of the bases of the 2 needles with sources of electrical signals through an electrical signal commutator. Layers 5 of non-metal can be made of a dielectric or semiconductor, or from a material having the properties of the inverse piezoelectric effect, or from a material with high ohmic resistance. The possibility of choosing materials of layers 5, as well as schemes for connecting needles to sources of electrical signals, provides a variety of therapeutic effects, the choice of therapeutic effects, as well as their combinations, depending on the purpose of reflexology.

Each needle is made in the form of a base 2 needles with at least one tip 3 and means for fixing the needle in the base 1 of the applicator in the form of annular beads 6. The metal coating of 4 needles is made on the basis of 2 needles with exposure of the tip 3 of the needle and the final portion of the metal coating 4 needles from the tip 3 needles. Layer 5 of non-metal is made between the base 2 of the needle and the metal coating 4 of the needle.

The base of the needle can be made in the form of a rod 9 with at least one pointed end (point) 3, and the means for fixing the needle in the base 1 of the applicator can be either in the form of a single collar 6, enveloping the rod 9 (Fig. 3), or in the form of two collars 6 (Fig. 4), or in the form of three collars 6, enveloping the rod 9 (Fig. 5), or in the form of a threaded section 10 on the rod 9 (Fig. 6), or in the form of a threaded section 10 and shoulder 6 on the rod 9 (Fig. 7), or in the form of disks 11 on the rod 9 (Fig. 8).

The base of the needle can be made in the form of a plate 12, with at least one tip 13 on one side of the plate 12, while the specified plate 12 is a means of fixing the needle in the base 1 of the applicator. In FIG. 13, 14 show an example of a four-pointed needle 13.

The base of the needle can be made of wire with bent in the vertical plane of the end sections 14 in the form of spikes with bends of the middle section 15 of the wire in the vertical and / or horizontal planes, while the middle section 15 wire is a means of fixing the needle in the base 1 of the applicator (Fig. 15, 16, 17). FIG. 15, 16 - bends of the middle section 15 of the wire in a vertical plane, FIG. 15, 17 - bends of the middle section 15 of the wire in the vertical and horizontal planes.

The tips of the needles can be made pointed, blunt or blunt (in Fig. 18: 18a, 18b, 18c - the base of the needle in the form of a rod, 18d, 18e - the base of the needle from the wire).

In FIG. 19, 20, examples of the applicator with needles are shown, the bases of which are made in the form of rods 9 with pointed ends (points) 3. Metal rods 4 and layers of non-metal 5 between the rods 9 and metal coatings 4 are made on the rods 9. The elastic base 1 of the applicator is made three-layer with two electrically conductive layers - the upper electrically conductive layer 16 in contact with the metal coatings of 4 needles, the lower electrically conductive layer 17 in contact with the rods 9 (the base of the needles), the middle layer 18 of the dielectric insulating ele also conduct the layers 16, 17 from each other. The upper 16 and lower 17 electrically conductive layers are means of electrical connection of metal coatings 4 needles and rods 9 (needle base) with sources of electrical signals. Means for fixing the needles in the base 1 of the applicator can be made in the form of collars 6 (Fig. 19), in the form of a collar 6 and a threaded section 10 on the rod 9 (Fig. 20).

In adjacent applicator needles, needle base materials (rods 9) and metal coating materials 4 are selected with different electrochemical potentials, as a result of which galvanic microcurrents occur in the epidermis of the user's skin, flowing between the needle bases, between the needle coatings, and also between the needle bases and their coatings that cause the effects of galvanization of the skin and electrophoresis with the transfer of many trace elements to the user's body. The base materials of the needles (rods 9) and metal coatings 4 can be selected from the group of metals, including iron, copper, chromium, nickel cobalt, aluminum, magnesium, zinc, tin, titanium, vanadium, beryllium, gold, platinum, palladium, strontium, as well as their alloys and oxides.

Non-metal can be either a dielectric or a semiconductor, or a material having the properties of the inverse piezoelectric effect, or a material with high ohmic resistance. When using a dielectric, the needle will act as a needle-electrode, with which it affects the user's body with electrical signals. When using a semiconductor material, it is possible to expose the skin of the user, for example, by infrared or ultraviolet radiation of the semiconductor material. Using materials with the properties of the inverse piezoelectric effect, can cause vibration of the needles, which enhances the mechanical effect of the needles. When using a material with high ohmic resistance, when the voltage is applied to the needle, thermal energy is generated that heats the needle, which ensures the thermal effect of the needles on the user's body. That is, the choice of non-metal provides additional therapeutic effects of the applicator.

In FIG. 21, 22 shows an example of the implementation of the applicator with needles, the bases of which are made in the form of a plate 12 with points 13 on one side of the plate 12. These plates 12 are a means of fixing the needles in the base 1 of the applicator. The elastic base 1 of the applicator is made three-layer with two electrically conductive layers - the upper electrically conductive layer 16 in contact with the metal coatings 4, the lower electrically conductive layer 17 in contact with the plates 12, the middle dielectric layer 18, insulating the electrically conductive layers 16, 17 from each other.

In FIG. 23, 24, 25 show examples of an applicator with needles, the bases of which are made of wire with end sections 14 bent in a vertical plane in the form of spikes with bends of the middle section 15 of the wire in the vertical and / or horizontal planes. The middle sections 15 of the wire are means of fixing the needles in the base 1 of the applicator. The base 1 of the applicator is made three-layer with two electrically conductive layers - the upper electrically conductive layer 16 in contact with the metal coatings 4, the lower electrically conductive layer 17 in contact with the middle sections of the wire 15, the middle dielectric layer 18, insulating the electrically conductive layers 16, 17 from each other.

In FIG. 24 shows an example of the execution of the middle sections 15 of the wire with bends in the vertical plane, in FIG. 25 - with bends in the vertical and horizontal planes.

At least one of the electrically conductive layers 16, 17 can be made in the form of electrically isolated from each other sections in contact with a given group of needles or with metal coatings of a given group of needles.

In FIG. 26, 27 shows an applicator in which the upper electrically conductive layer is made in the form of sections 19Y, 19B2 ... 19bn, 19c1, 19c2 ... 19sp that are electrically isolated from each other and in contact with metal coatings of 4 predetermined needle groups. The sections 19Y, 19b2 ... 19bn are connected to the terminals b, b2 ... bn. The sections 19c1, 19c2 ... 19sp are connected to the terminals c1, c2 ... cn. The sections 19Y, 19B2 ... 19bn, 19c1, 19c2 ... 19sp are separated by insulating tracks 20. The lower conductive layer 17 is in contact with the rods 9 (needle bases) and connected to terminal a (common terminal). Electrical terminals are connected to terminals a M, b2 ... bn, c1, c2 ... cn appropriate size and shape from the generator (s) of electrical signals.

In FIG. 28-31 shows an applicator in which the upper electrically conductive layer is made in the form of sections 21 d1, 21d2 ... 21 dn electrically isolated from each other, oriented in the transverse direction of the applicator base and in contact with the metal coatings of 4 transverse rows of needles, and the lower electrically conductive layer - in the form of sections 21e1, 21e2 ... 21ep electrically isolated from each other, oriented in the longitudinal direction of the base of the applicator and in contact with the rods 9 (bases) of the longitudinal rows of needles, Sections 21 d1, 21d2 ... 21dn are connected to the terminals ami d1, d2 ... dn. The sections 21 e1, 21e2 ... 21ep are connected to the terminals e1, e2 ... ep. Sections 21 d 1, 21d2 ... 21dn are separated by insulating paths 22, and sections 21e1, 21e2 ... 21ep are separated by insulating paths 23. Electrical signals corresponding to terminals d1, d2 ... dn, e1, e2 ... en are connected magnitudes and shapes from the generator (s) of electrical signals.

The specified implementation of the applicator allows you to bring electrical signals of a given size and shape, both to individual needles and to specified groups of needles. The applicator can also be used as a diagnostic tool, with which it is possible to scan both individual sections and individual points on the user's body, determining their electrical parameters.

The needles can be made with at least two tips 24, 25, which protrude beyond the base of the applicator 1 on opposite sides of the base 1 with the formation of two working sides of the applicator: the tips 24 form one working side of the applicator, the tip 25 - the other. The points 24 are pointed, the points 25 are blunted, which determines different therapeutic effects when using one or another working side of the applicator (Fig. 32).

Permanent magnets 26 (FIG. 33) can be mounted on the rods 9 (needle bases) to provide a constant magnetic field to the user's body, or solenoids 27 connected to a source of electrical signals (FIG. 34). The solenoids 27 can be used as electromagnets or as inductors for heating the rods 9 for thermal impact on the user's body.

The base 1 of the applicator can be made with a built-in power source 28, electric signal sources 29 and a switch 30, with which the corresponding electrically conductive sections 19M, 19L2 ... 19bn, 19s1, 19s2 ... 19sl are connected to the electric signal sources 29 according to a predetermined algorithm (fig. 35).

The base of the applicator may have a different spatial configuration. So, the base of the applicator may have a flat spatial configuration, for example, in the form of a rectangular sheet 1 (Fig. 27), or tape 31 (Fig. 36), or petals 32 (Fig. 37), or shoe insole 33 (Fig. 38) or other flat shapes.

The applicator base may have a three-dimensional spatial configuration, for example, in the form of a cylinder 34 (FIG. 39), or a sphere 35 (FIG. 40), or a hemisphere 36 (FIG. 41), or other three-dimensional shapes.

The spatial configuration of the base in the form of a cylinder 34, or in the form of a sphere 35 can be the basis of a cylindrical roller massager (Fig. 42) or a spherical roller massager (Fig. 43).

The spatial configuration of the base is determined by the features of the applicator (rug, roller, massager, etc.), as well as the shape of the areas of the body on which the reflexology procedure is performed.

The applicator can be made with means for fixing the applicator on the user's body, for example, in the form of free tapes 37 (Fig. 44), hooks 38 (Fig. 45), buckles 39 and free tape 40 (Fig. 46), a belt 41 connected to the base 1 of the applicator using sling 42 (Fig. 47, 48).

The applicator is used to prevent, eliminate or reduce pain in cases of radiculitis, osteochondrosis, to increase the body's resistance, relieve pain in the muscle tissue of the back, cervical region, arms and legs, to relieve joint pain and restore mobility in the joints and spine, to normalize sleep, relieving stress and headaches, to restore and improve performance in the conditions of production, in everyday life and in sports. The applicator is intended for both specialists and ordinary consumers.

The applicator is used in a known manner - it is applied by the working side to a part of the body, pressed and held in this position for a predetermined period of time. The therapeutic effect is provided by the mechanical action of the tip of the needles on the user's body, by galvanic microcurrents arising between the metal coatings of the needles and needles (the effects of galvanization and galvanic electrophoresis), by the exposure of the user's body to electrical signals of various sizes and shapes.

Claims

Claim

1. The applicator for reflexology, containing an elastic base (1) of the applicator of a given spatial configuration and a needle, the base (2) of which is fixed in the base (1) of the applicator with the possibility of protruding the tips (3) of the needles beyond the base (1) of the applicator and made of metal coatings (4), characterized in that between the metal coatings (4) and the bases (2) of the needles made layers (5) of non-metal, while the applicator is made with means of electrical connection of the bases (2) of needles and metal coatings (4) of needles with sources electric si gnalov.

2. The applicator according to claim 1, characterized in that the non-metal is either a dielectric, or a semiconductor, or a material having the properties of an inverse piezoelectric effect, or a material with high ohmic resistance.

3. The applicator according to claim 1, characterized in that the base (2) of the needles is made in the form of a rod with at least one point (3), and the means for fixing the needles in the base (1) of the applicator are made in the form of at least , one shoulder (6) on the rod, or in the form of a threaded section (10) on the rod, or in the form of disks (1 1) on the rods, or combinations thereof.

4. The applicator according to claim 1, characterized in that the base (2) of the needles is made in the form of a plate (12) with at least one tip (13) on at least one side of the plate (12), with this plate (12) is a means of fixing the needle at the base of the applicator.

5. The applicator, characterized in that the needle base is made of wire with at least one bend in the horizontal and / or vertical plane, while the end sections (14) of the wire are made in the form of needle tips, and the middle section (15) wire is a means of securing the needle at the base of the applicator.

6. The applicator according to claim 1, characterized in that the means for electrically connecting the needles to the sources of electrical signals are made in the form of insulated conductive layers (16, 17) of the base of the applicator in contact with the base of the needles or with metal coatings of the needles.

7. The applicator according to claim 1, characterized in that the needles are made with at least two tips (24, 25) protruding beyond the base of the applicator from opposite sides of the base with the formation of two working sides of the applicator.

8. The applicator according to claim 1, characterized in that either permanent magnets (26) or solenoids are mounted on the base of the needles. (27)

9. The applicator according to claim 1, characterized in that the base of the applicator has a flat spatial configuration made in the form of a rectangular sheet (1), or ribbons (31), or petals (32), or a shoe insole (33), or other flat figures.

10. The applicator according to claim 1, characterized in that the base of the applicator has a three-dimensional spatial configuration made in the form of a cylinder (34) or a sphere (35), or a hemisphere (36), or similar three-dimensional forms, or a combination of these three-dimensional forms.

11. The applicator according to claim 1, characterized in that it is made with means for fixing the base of the applicator to the user's body.