WO2019240733A1 - Reflexology applicator - Google Patents

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 includes an elastic base, needles fastened in the elastic base, the points of which protrude out of the elastic base and form a working side of the applicator, and electrical conductors connecting the needles. Moreover, in needle connecting regions, the electrical conductors are bent in at least one plane.

Description

 Applicator for reflexology 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 in medical institutions and in domestic conditions.

 The needle applicators for reflexology, as a rule, are made in the form of an elastic base with needles fixed in it, as elements of a reflex effect, the tips of which extend beyond the elastic base, forming the working side of the applicator.

 Needle applicators are widely known that are made with the means of electrically connecting the needles within the applicator to connect the needles to electric signal sources according to a predetermined algorithm or to control galvanic microcurrents, the generators of which are the system “applicator needles - the body of the user”, which works without connecting external sources of electricity .

 So, it is known a device for reflexology (Ukrainian patent for the invention Ns 95708, IPC A61 H 39/08, filing date 08/02/2010), containing an elastic base, in which are fixed needles with tips that protrude beyond the base with the formation of the working side of the device, which contacts the surface (skin) of the user's body when using the applicator.

 The needles are electrically connected in accordance with a predetermined algorithm with external sources of electrical signals of various sizes and shapes, for example, direct voltage, alternating voltage, unipolar or bipolar pulses. Means for electrical connection of the needles are made in the form of linear conductors connected to the corresponding needles and placed inside the elastic base.

The implementation of the means of electrical connection of the needles in the form of linear conductors connected to the corresponding needles and placed inside the elastic base eliminates the possibility of elastic deformation of the base of the applicator along the linear conductors or leads to damage (rupture) of the conductors, which reduces the functionality of the applicator and its reliability As a prototype, a device for reflexology with means for electrical connection of needles, known according to the patent of Ukraine for the invention N ° 95708, IPC A61 H 39/08, the filing date of the application is 08.02.2010.

 The device for reflexology contains an elastic base in the form of a rectangular sheet in which needles are fixed, the tips of which extend beyond the elastic base with the formation of the working side of the applicator. The needles are made of metals and / or their alloys with different electrochemical potentials and are installed at the base of the applicator with alternating needles of various metals and / or their alloys in any ratio. Selected groups of needles are electrically connected by linear conductors in accordance with a predetermined algorithm for the electrical connection of needles. Each conductor is equipped with an input and at least one output with the ability to connect to an external source of electrical signals. As an external source of electrical signals can be a DC or AC generator. Line conductors may be located inside the elastic base and / or on one side of the base.

 Common features of the prototype and the claimed solution are: an applicator for reflexology, which includes an elastic base of a given spatial configuration, needles fixed in an elastic base, the tips of which extend beyond the elastic base to form the working side of the applicator, electrical conductors connecting the needles in accordance with a given needle electrical connection algorithm.

 As in the above analogue, during elastic deformation of the base during use of the applicator, the linear conductors connecting the needles undergo tensile deformation, which, taking into account their linear stiffness, virtually eliminates the possibility of elastic deformation of the base of the applicator along linear conductors or leads to damage (rupture) of the conductors , which reduces the functionality of the applicator and its reliability.

 The basis of the invention is the task of expanding the functionality of the applicator and its reliability.

The problem is solved in that in the applicator for reflexology, which includes an elastic base of a given spatial configuration, needles fixed in an elastic base, the tips of which extend beyond the elastic base with the formation of the working side of the applicator, electrical conductors connecting the needles in accordance with a given algorithm of electric connection of needles, in accordance with the invention, electrical the conductors in the areas of the connection of the needles have a curved configuration in at least one plane.

 These signs are essential features of the invention, as they are necessary and sufficient to achieve a technical result - the expansion of the functionality and reliability of the applicator.

 The implementation of the electrical conductors in the areas of connection of the needles with a curved configuration in at least one plane provides the possibility of deformation of the conductors by bending them. In the process of elastic deformation of the base of the applicator in the proposed solution, the electrical conductors are bent, which does not reduce the elasticity of the base and prevents damage to the conductors, which extends the functionality of the applicator and its reliability.

 Electrical conductors can be made in the form of a broken line with at least two links.

 Electrical conductors can be made in the form of a wavy line.

Electrical conductors can be made in the form of a curved line with at least one loop.

 Electrical conductors can be made in the form of electrical wires fixed to / on the base of the applicator, and / or in the form of electrically conductive sections of the base of the applicator, and / or metal coatings made on the basis of the applicator.

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

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

 FIG. 1 - Applicator for reflexology, cross section, the location of the electrical conductors at the base of the applicator.

 FIG. 2 - Applicator for reflexology, cross section, the location of the electrical conductors on one of the sides of the base of the applicator.

 FIG. 3 - Applicator for reflexology, types A, B in FIG. 1, 2, the implementation of electrical conductors in the form of a broken line with two links.

 FIG. 4 - Applicator for reflexology, types A, B in FIG. 1, 2, the implementation of electrical conductors in the form of a broken line with four links.

 FIG. 5 - Applicator for reflexology, types A, B in FIG. 1, 2, the implementation of electrical conductors in the form of a broken line with five links.

FIG. 6 - Applicator for reflexology, types A, B in FIG. 1, 2, the implementation of electrical conductors in the form of a wavy line. FIG. 7 - Applicator for reflexology, types A, B in FIG. 1, 2, the implementation of electrical conductors with a single loop.

 FIG. 8 - Applicator for reflexology, types A, B in FIG. 1, 2, the implementation of electrical conductors with two loops.

 FIG. 9 - Applicator for reflexology, cross section, the implementation of electrical conductors in the form of conductive sections of the base of the applicator.

 FIG. 10 - Applicator for reflexology, cross section, the implementation of electrical conductors in the form of metal coatings on one side of the base of the applicator.

 FIG. 11 - Applicator for reflexology, types B, D in FIG. 9, 10.

 FIG. 12 - Applicator for reflexology, an example of the applicator with needles in the form of U-shaped staples connected by wires on one of the sides of the base of the applicator.

 FIG. 13 - Applicator for reflexology, view D in FIG. 12.

 FIG. 14 - Applicator for reflexology, an example of an applicator with needles in the form of U-shaped staples connected by wires on two sides of the base of the applicator.

 FIG. 15 - Applicator for reflexology, view E in FIG. 14.

 FIG. 16 - Applicator for reflexology, view G in FIG. 14.

 FIG. 17 - Applicator for reflexology, an example of the applicator, the base of which is made with conductive sections connecting the needles, a transverse section.

 FIG. 18 - Applicator for reflexology, view K in FIG. 17.

 FIG. 19 - Applicator for reflexology, an example of the applicator, the base of which is made in the form of a flexible printed circuit board.

 FIG. 20 - Applicator for reflexology, view L in FIG. 19 the implementation of the printed conductors with the connection of adjacent rows of needles to opposite poles of the source of electrical signals.

 FIG. 21 - Applicator for reflexology, view L in FIG. 19 the implementation of the printed conductors with the connection of adjacent needles to the opposite poles of the source of electrical signals.

 FIG. 22 - Applicator for reflexology, an example of the applicator, the needles of which are made as needle electrodes, and the base is in the form of a bilateral flexible printed circuit board.

 FIG. 23 - Applicator for reflexology, view M in FIG. 22.

FIG. 24 - Applicator for reflexology, type H in FIG. 22. FIG. 25 - Applicator for reflexology, scheme of elastic deformation of the base of the applicator according to the claimed solution.

 FIG. 26 - Applicator for reflexology, scheme of elastic deformation of the base of the applicator according to the prototype.

 FIG. 27 - Applicator for reflexology, an example of the implementation of the applicator with nodes of reflex exposure, cross section.

 FIG. 28 - Applicator for reflexology, section BB in FIG. 27.

 FIG. 29 - Applicator for reflexology, view P in FIG. 27.

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

 31 - Applicator for reflexology, node I in FIG. thirty.

 FIG. 32 - Applicator for reflexology, the implementation of the base in the form of a tape.

 FIG. 33 - Applicator for reflexology, the implementation of the base in the form of petals.

 FIG. 34 - Applicator for reflexology, the implementation of the base in the form of a shoe insole.

 FIG. 35 - Applicator for reflexology, the implementation of the base in the form of a cylinder.

 FIG. 36 - Applicator for reflexology, the implementation of the base in the form of a sphere.

 FIG. 37 - Applicator for reflexology, the use of a cylindrical base in a cylindrical massage roller.

 FIG. 38 - Applicator for reflexology, the use of a spherical base in a spherical massage roller.

The applicator for reflexology includes an elastic base 1 of a given spatial configuration, needles 2 fixed in an elastic base 1, the tips of which extend beyond the elastic base 1 to form the working side of the applicator, as well as electrical conductors 3 connecting the needles 2 in accordance with a predetermined electrical connection algorithm needles 2. Electrical conductors 3 in the areas of connection of the needles 2 have a curved configuration in at least one plane. The curvilinear configuration of the conductors 3 can be performed, for example, in the form of a broken line with at least two links, or in the form of a wavy line, or in the form of a curved line with at least one loop. Electrical conductors can be made in the form of electric wires fixed to / on the base of the applicator, and / or in the form of electrically conductive sections of the base of the applicator, and / or metal coatings made on the basis of the applicator. In FIG. 1 shows an example of an applicator (cross section), which contains an elastic base 1 in which the needles 2 are fixed, connected by electric wires 3 in accordance with a predetermined algorithm for the electrical connection of the needles 2. The needles 2 are made with annular beads 4, as means for fixing the needles 2 in the base 1. Electric wires 3 are located in the base 1 of the applicator.

 In FIG. 2 shows a similar applicator. The difference is that the electric wires 3 are located on one side of the base 1 of the applicator (on the back side of the base 1).

 Electric wires at the sites of connection of the needles 2 may have a different curved configuration. So in FIG. 3 shows an example of electric wires in the form of broken lines 5 with two links (5a, 56), in FIG. 4 - in the form of broken lines 6 with three links (6a, 66, 6c), in FIG. 5 - in the form of broken lines 7 with five links (7a, 76, 7c, 7d, 7d), in FIG. 6 - in the form of wavy lines 8, in FIG. 7 - with one loop 9, in FIG. 8 - with two loops 10, 1 1 or several loops in the form of a spring 12.

 Electrical conductors can be made in the form of conductive sections 13 of the base 1 of the applicator (Fig. 9) or in the form of metal coatings 14 on one side of the base 1 of the applicator (Fig. 10). Conductive sections 13 or metal coatings 14 are made curved, for example wavy (Fig. 1 1).

 In FIG. 12, 13 shows an example of an applicator with needles in the form of U-shaped staples, the ends of which 15 extend beyond the base 1 and form the working side of the applicator, and the cross members 16 are made with loops 17, the vertices of which extend beyond the base 1 from the side opposite to the protruding the ends of 15 needles (from the back of the base 1). The needles in the longitudinal rows are connected by wires 18 located under the tops of the loops 17 on the back side of the base 1. This embodiment allows you to connect adjacent rows of needles to opposite poles of the source of electrical signals. The wires 18 can be made, for example, in the form of a broken line 18a with two links, or in the form of a broken line 186 with three links, or in the form of a wavy line 18c (Fig. 13).

In FIG. 14-16 show an example of an applicator with needles in the form of U-shaped staples, the ends of which 15 extend beyond the base 1 and form the working side of the applicator, and the cross members 16 are made with loops 17, the vertices of which extend beyond the base 1 from opposite sides of the base 1 applicator. Loops 17, the peaks of which protrude from the back of the base 1, are connected by wires 19. Loops 17, whose peaks protrude from the working side of the base 1, are connected by wires 20. In FIG. 15 shows an example implementation wires 20 in the form of a broken line 20a with three links, or in the form of a broken line 206 with five links, or in the form of a broken line 20b with seven links. In FIG. 16 shows an exemplary embodiment of wires 19 in the form of a wavy line 19a, or in the form of a line 196 with two loops, or in the form of a line 19b with four loops.

 In FIG. 17-18 show an example of the applicator, the base 1 of which is made in the form of a tape with conductive sections L-L7 connecting the needles 2 in the longitudinal rows. A power supply 21, generators 22 of various electrical signals and a switch 23 are mounted in the base 1 of the applicator. Electrical signals of various sizes and shapes can be connected to different conductive sections L-L7 through the switch 23 and the loop 24.

 In FIG. 19-21 shows an example implementation of the applicator, the base of which is made in the form of a flexible printed circuit board. The flexible printed circuit board has a base 25 on which the contact pads 26 are connected, connected by printed conductors 27. The holes are made in the contact pads 26, into which the shanks 28 of the needles 2 are inserted. The shanks 28 are connected to the contact pads 26 by soldering. The printed conductors 27 may have a different topography depending on the algorithm for electrically connecting the needles 2. In FIG. 20 shows the construction of printed conductors 27 with the ability to connect adjacent rows of needles 2 to opposite poles of the source of electrical signals. The printed conductors 27 in the areas of electrical connection of the needles 2 are made in the form of a broken line with two links. In FIG. 21 shows the construction of printed conductors 27 with the ability to connect adjacent needles 2 to opposite poles of the source of electrical signals. The printed conductors 27 in the areas of electrical connection of the needles 2 are made with one loop.

In FIG. 22-24 show an exemplary embodiment of an applicator with needle electrodes. The base of the applicator is made in the form of a two-sided flexible printed circuit board 25. On the working side of the printed circuit board 25, pads 29 are made, which are connected by printed conductors 30. On the back side of the printed circuit board 25, pads 31 are made, which are connected by printed conductors 32. Needles 2 are made of metal coatings 33 and dielectric layers 34, electrically insulating the metal coating 33 from the needles 2. Contact pads 29, 31 are made with holes in which the shanks 28 of the needles are inserted 2. Contact pads and 29 on the working side of the printed circuit board 25 are soldered to the metal coatings 33 of the needles 2. The shanks 28 are connected to the pads 31 on the back side of the printed circuit board 25. The printed conductors 30, 32 are connected to opposite poles of the source of electrical signals. This embodiment of the applicator allows you to affect the user's body electrical signals of various sizes and shapes. The printed conductors 30, 32 are made, for example, in the form of wavy lines (Fig. 23, 24).

 In FIG. 25-26 shows a diagram of the elastic deformation of the base of the applicator according to the claimed solution (Fig. 25), and the prototype (Fig. 26). In the process of elastic deformation of the base 1 in the proposed solution, the conductors 3 are bent, which does not reduce the elasticity of the base 1 and prevents damage to the conductors 3 (Fig. 25). With elastic deformation of the base 1 in the solution according to the prototype, the conductors 3 are stretched, which virtually eliminates the possibility of elastic deformation of the base 1 or leads to damage (rupture) of the conductors 3 (Fig. 26).

 In FIG. 27-31 shows an example implementation of the applicator with nodes of reflex exposure. The needles are made in the form of U-shaped staples, the ends 15 of which extend beyond the base 1 and form the working side of the applicator, and the cross members 16 are made with loops 17, the vertices of which extend beyond the base 1 from opposite sides of the base 1 of the applicator. The needles are located in the longitudinal and transverse rows of the base 1 of the applicator. The nodes 33 of the reflex effect are formed by four protruding ends of 15 different needles with different electrochemical potentials. The ends 15 of the needles can be in contact with each other or be electrically isolated in the nodes 33 of the reflex effect. In the first case, the ends of the 15 needles form galvanic pairs, causing the known effects of skin galvanization and electrophoresis. In the second case, the nodes 33 of the reflex effect can serve as electrodes, with which you can act on the user's body with electrical signals of various sizes and shapes. In FIG. 27-30 shows an example of the implementation of the applicator with the isolated ends of 15 needles in the nodes 33 of the reflex effect (located at a distance from each other). The loops 17 of the needles located in the transverse rows extend beyond the base 1 from the working side of the applicator and are connected by wires 34 located under the tops of the loops 17 on the working side of the applicator. The loops 17 of the needles located in the longitudinal rows protrude beyond the base 1 from the back of the applicator and are connected by wires 35 located under the tops of the loops 17 on the back of the applicator. The wires 34, 35 in the areas of the connection of the needles are made in the form of broken lines with two links. The wires 34, 35 are connected to the opposite poles of the source of electrical signals. As a result, the nodes 33 are electrodes with four poles (Fig. 31).

The base of the applicator may have a different spatial configuration. So, the base of the applicator may have a flat spatial a configuration, for example, in the form of a tape 36 (FIG. 32), or petals 37 (FIG. 33), or a shoe insole 38 (FIG. 34), or other flat figures.

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

 Spatial configurations of the base in the form of a cylinder 39, or in the form of a sphere 40 can be the basis of a cylindrical roller massager 41 (Fig. 37) or a spherical roller massager 42 (Fig. 38).

 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.

Claims

Claim

1. The applicator for reflexology, including an elastic base (1) of a given spatial configuration, needles (2) fixed in an elastic base (1), the tips of which extend beyond the elastic base (1) to form the working side of the applicator, electrical conductors (3) connecting needles (2) in accordance with a predetermined algorithm for electrical connection of needles (2),

 characterized in

that the electrical conductors (3) in the areas of the connection of the needles (2) have a curved configuration in at least one plane.

2. The applicator according to claim 1, characterized in that the electrical conductors are made in the form of a broken line (5) with at least two links.

3. The applicator according to claim 1, characterized in that the electrical conductors are made in the form of a wavy line (8).

4. The applicator according to claim 1, characterized in that the electrical conductors are made in the form of a curved line (9) with at least one loop.

5. The applicator according to claim 1, characterized in that the electrical conductors are made in the form of electrical wires, (3) fixed in / on the base (1) of the applicator, and / or in the form of electrically conductive sections (13) of the base (1) of the applicator, and / or metal coatings (14) made on the basis of (1) the applicator.

6. The applicator according to claim 1, characterized in that the base (1) of the applicator has a flat spatial configuration.

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