RU2089155C1 - Galvanoipplicator - Google Patents

Abstract

FIELD: medial equipment. SUBSTANCE: galvanoipplicator has flexible back 1 made from fabric, film etc, galvanoipplicator members 2 positioned on back 1 composed of mating figures such, as hexagons, squares, circles etc. All sides of members 2 are positioned with gap between them at least equal to integument shift. Needles 3 are positioned at one side of each member 2 so that their points are oriented away from back 1. Each member 2 has positive electrodes 4 and/or negative electrodes 5. Members 2 may be fixed on back 1 by glue, threads or any other known means or method. EFFECT: increased efficiency in stimulating exchange processes, resorption of congestions, therapy of osteochondrosis and radiculitis, reduced procedure time and wider operational capabilities. 11 cl, 18 dwg

Description

 The invention relates to medical equipment and can be used to stimulate metabolic processes, resolving congestion, treat osteochondrosis and radiculitis, as well as improve human performance, for example, in coaching practice to regulate the functional state of an athlete.

A device for influencing the reflex zones of the foot, containing the upper supporting profiled plate with protrusions on the working surface [1]
The disadvantages of the known device is the low effectiveness of the impact and low functionality due to the limited physical nature of the impact, namely, the mechanical type of irritation of the entire surface of the skin, or reflex zones.

Known electrical stimulator containing a base for attaching needles, made in the form of electrically conductive layers separated by a dielectric gasket, while in the upper layer of the base between the needles in a checkerboard pattern holes are made in which are placed needles attached to the lower layer, and the needles of two groups associated with different layers, are electrically isolated from each other and connected to different outputs of the pulse generator, moreover, the working ends of the needles of different groups are located in two parallel planes, the distance between which leaves 0.15-0.3 from the distance between the working ends of the nearest needles of one group, while the stimulator is equipped with a current detector connected in series with the generator, and each conductive layer and the metal part of the group of needles attached to it are made in the form of a single metal coating applied on dielectric strip [2]
The known device uses a combined effect using non-puncturing needles and electric current, however, its significant drawback is the possibility of significant side effects as a result of using an external energy source of considerable power and relatively high voltages applied from the outside without the needs of the body, and also has great complexity.

Known device for improving human performance ("Kuznetsov iplikator"), containing a group of elements in the form of a base with needles located on an elastic base so that all sides of the elements have a gap between them, the value of which is not less than the possible amount of displacement of the skin [3]
The known device practically does not cause side effects during and after use, has exceptional simplicity and manufacturability, as well as high operational amenities, however, it has low impact efficiency and low functionality due to the mechanical nature of the impact with non-piercing needles, which leads to long treatment periods .

 The aim of the invention is to increase the effectiveness of the impact, reduce the time of the procedure and expand the functionality while maintaining all the advantages of the well-known device "Kuznetsov iplikator" by combining the mechanical effects of non-piercing needles and the electrical effects produced by the body according to its needs and not producing side effects.

 To achieve this goal in a known device to improve human performance, the elements have positive and negative electrodes connected to each other. In addition, the positive and negative electrodes are made of electrically conductive materials with different electrochemical potentials and can be placed on each iplator element together, or separately positive on some elements, negative on others. In addition, positive and negative electrodes can be made in the form of positive and negative applicator elements, made at the same time with the needles, or in the form of positive and negative needles, or film in the form of positive and negative thin layers covering the surface of the applicator elements from the side of the needles together with them, moreover, the positive and negative electrodes can be of any type, or of various types in different combinations. In addition, the subsequent layer of the film electrode of one sign partially covers the previous layer of the electrode of another sign. In addition, the positive electrode of each iplator element is the element itself, made entirely of copper, and the negative electrode is a layer of electrically conductive material with another electrochemical potential deposited on a part of the surface of the element from the side of the needles together with the corresponding needles. In addition, the electrical connections between the elements are made using an elastic base, which has metallization on the part of the arrangement of the elements, and the latter have electrical contact with it. In addition, the metallized elastic base contains printed conductors of interconnects and contact pads on which the applicator elements are located so that the latter have electrical contacts with the contact pads and are fixed to them, for example, by soldering, or using an adhesive layer deposited on the contact pad, in the latter case, the elastic base also contains a protective film located on top of the adhesive layer and removed when the elements are placed on it. In addition, the rear blunt ends of the needles made of dissimilar electrically conductive materials protrude a small amount on the back of the dielectric base of each element through an elastic base, an additional removable programmable film with printed conductors of inter-needle and interelement joints and contact pads or metallized holes for the number of needles of all elements is additionally introduced. moreover, the programmable film is placed on the other side of the elastic base with respect to the located elements so that the fifth ends of the element needles had electrical contact with pads or metallized holes; the removable programmable film can be fixed on an elastic basis, for example, using an adhesive layer and have a protective transparent film located on top of the adhesive layer and removed before the location of the programmable film on an elastic basis. In addition, all the elements are interconnected and made integral with the elastic base and together with it represent a thin film of a substrate with needles, from which sections of the required sizes and configurations can be cut. In addition, on the needle side, the substrate film has an adhesive layer. In addition, one or more elastic substrates with applicator elements similar to the first are additionally introduced into it, moreover, all elastic substrates or elements on them are electrically connected, for example, by flexible wires.

 Figure 1 shows a General view of a general therapeutic galvanic applicator in plan; figure 2 galvanic applicator element of a dielectric material with sprayed film electrodes and its section; figure 3 is a sectional view of an embodiment of a galvanic applicator cell made entirely of copper with a sprayed film second electrode; figure 4 General view and section of a galvanic applicator element with metal needles of two types of metals; in Fig. 5, an example embodiment of the galvanic applicator element of Fig. 4 in section with inter-needle connections on the back side of the base of the element; Fig.6 an example of the implementation of a general therapeutic galvanic applicator element with multilayer electrodes; Fig.7 is a section of a galvanic applicator element with a local galvanic effect; on Fig section section of a galvanic applicator element with a local galvanic effect and multilayer electrodes; Fig.9 is an example of the implementation of the galvanic applicator elements of two types with a positive or only negative electrode, made in the form of a thin metal film deposited on dielectric and applicator elements; figure 10 an example of the implementation of galvanic applicator elements with electrodes in the form of needles from dissimilar metals and dielectric metallized bases; in FIG. 11 is an example of the implementation of all-metal galvanic applicator elements with electrodes in the form of needles of dissimilar metals and metal bases; on Fig an example of the implementation of all-metal elements of two characters; on Fig an example of the implementation of inter-needle connections in the form of printed conductors on an elastic basis for galvanic applicator elements of dissimilar metals and a section of such an element; on Fig example implementation of a galvanic applicator with a programmable film of inter-needle connections for the elements of Fig; on Fig an example of the implementation of interconnects in the form of printed conductors on an elastic basis for the galvanic elements in Fig.9-11; in Fig.16 an example of the implementation of the inter-element connections of the elements of Fig.9-11 using a fully metallized elastic base with an example of connecting the two bases with a flexible wire and an example of the use of a galvanic applicator; on Fig an example of a galvanic applicator with a wireless connection of elastic foundations of its use; in Fig.18 an example of performing a galvanic applicator in the form of a film needle patch with an adhesive surface and cutting out of it a portion of the required size and configuration.

 The galvanic applicator (Fig. 1) contains an elastic base 1 made of fabric or film with galvanic applicator elements 2 arranged on it in random order, made in plan in the form of geometric shapes that combine with each other, for example, a hexagon, square, circle, etc. in FIG. 2-8, moreover, all sides of the elements 2 based on 1 have a gap between themselves, the value of which is less than the possible displacement of the skin; needles 3 located on one side of each element 2, directed by points from the base 1; each galvanic applicator element 2 has positive 4 and / or negative 5 electrodes; the elements 2 can be fixed on the base 1 with glue, threads or in any other known manner.

 The galvanic applicator element 2 (figure 2) for general therapeutic purposes contains a dielectric base 6 made integral with the needles, or the needles 3 are made of the same metal, for example, steel and are mounted in the base 2, and the positive electrodes 4 and the negative 5 electrodes covering the needle surface of the element 2 made in the form of thin layers sprayed onto a surface with needles 3 from electrically conductive materials with different electrochemical potentials, moreover, a layer of one electrode, for example, 4, completely covers the surface of element 2 state, and a layer of another electrode, for example, 5, is deposited on top of the first one and half-covers the surface of the element.

 The galvanic applicator element 2 (Fig. 3) contains a base 6 made integrally with the needles 3 made entirely of copper, which is a positive electrode 4 and a layer deposited on a part of its needle surface, together with the needles 3 located on this part, of the negative electrode 5.

 An example of the implementation of the galvanic applicator element 2 with metal needles 3 (Fig. 4,5) contains needles 3 of two types of dissimilar conductive materials with different electrochemical potentials, which are positive 4 and negative 5 electrodes, needles 3 are mounted in a dielectric base 6 and are interconnected electrically in pairs 4-5 or groups, and electrical connections 7 can be made differently, for example, from the side of the needles 3, or from the opposite side, or inside the base 2.

 An example of a galvanic applicator element 2 of a general therapeutic type with multilayer electrodes (Fig. 6) contains a dielectric base 6 made integral with the needles 3, or the needles 3 are made of metal of the same type, for example, steel and mounted in the base 6; positive 4 and negative 5 electrodes made of electrically conductive materials of two types are deposited on the needle surface of element 2 together with needles 3 and on top of each other in the form of thin layers, moreover, the layers alternate in sign and each subsequent layer partially covers the previous one.

 An example of a galvanic applicator element 2 with a local galvanic effect (Fig. 7.8) contains a dielectric base 6 with dielectric or metal needles 3 from one of a metal, for example, steel and two or more layers of positive 4 and negative 5 electrodes, moreover, the first layer of one an electrode, for example, a positive 4, is deposited on the entire needle surface of the element 2, a second, for example, a negative 5 electrode, is deposited on the entire needle surface of the element 2 on top of the first except for the tips of the needles 3 (Fig. 7), if trodes formed multilayer (8), subsequent layers are deposited on top of the previous whole surface of a needle member 2 except for the tips of the needles 3, so that at the tip open all previous layers of electrodes and alternating in sign with the previous layers of electrodes.

 An example of the implementation of the galvanic applicator elements 2 (Fig.9-12) contains two types of elements 2, which are entirely positive 4 or negative 5 electrodes, moreover, the base 6 of both types of elements 2 can be dielectric with dielectric or metal needles 3, for example, steel, and the positive 4 electrode is formed by a thin layer of the corresponding conductive material covering the entire needle surface of one element 2, and the negative 5 electrode also covers the entire needle surface of the other element 2 (Fig. 9); the base 6 can be dielectric with metal needles 3 made of dissimilar metals (Fig. 10), moreover, on one element 2 there are needles 3 of only positive type 4, and on the other element 2 of only negative type 5; the base 6 of each element 2 has a metallization, for example, from the side of the needles 3, which connects them all together electrically within the same element 2; the base 6 of the elements 2 can also be made metal of one type of metal (for example, copper) with metallic needles 3 made of dissimilar metals mounted in it (11), moreover, the needles 3 forming the positive electrode 4 are placed on one element 2, and needles forming a negative 5 electrode on another element 2; the base 6 can be made completely metal at the same time with the needles 3, moreover, some elements 2 are made of metal with positive electrochemical potential and are positive 4 electrodes, and other elements 2 are made of metal with negative potential and are negative 5 electrodes (Fig. 12).

 An example of the implementation of a galvanic applicator with inter-needle and inter-element connections in the form of printed conductors (Fig. 13) contains an elastic base 1 made, for example, of a dielectric film with Ipplicator elements 2 located on it, with needles 3 made in the form of positive 4 and negative 5 electrodes from dissimilar metals, and a dielectric base into which the needles 3 are mounted so that their blunt ends protrude a small amount from the back of the base 6 of each element 2; the elements 2 are located on one side of the base 1 in an arbitrary order so that the blunt ends of the needles pass through the base 1 and protrude a small distance from its other side, on which the printed conductors 7 are electrically connected between the needles 3 of the various elements 2 so that that the positive needles 4 are connected by conductors 7 with negative 5, moreover, the conductors 7 end with pads 8 with holes in which the blunt ends of the needles are soldered or glued with electrically conductive glue 3 elements 2, soldering or gluing is performed on the side of the conductors 7 of the elastic base 1.

 An example of a galvanic applicator with a replaceable programmable film of interelectrode connections (Fig. 14) contains an elastic base 1 made of fabric or a dielectric film with galvanic applicator elements 2 on Fig. 13 with needles 3, positive 4 and negative 5, made of dissimilar metals, moreover, the blunt ends of the needles protrude from the back of the dielectric bases 6 of the elements 2, pass through the base 1 and protrude by a small amount on its other side; on top of the elastic base 1 from the side of the protruding ends of the needles 3, is put on them and fixed on the base with an adhesive layer 10 deposited on its one side, an elastic thin programmable film 11 with printed conductors of the interconnects 7 according to a certain topological pattern and pads 8 with holes 9 with metallization through which pass and contact with them the electrically blunt ends of the needles 3; if necessary, the programmable film 11 can be replaced by another with a different layout of printed conductors; the programmable film 11 comprises a transparent protective film 12 covering its adhesive layer 10 and which is removed by fixing the programmable film 11 on the basis of 1.

 An example of a galvanic applicator (Fig. 15) with enhanced galvanic effect and elements 2 of Figs. 9-12 comprises an elastic base 1 with printed conductors 7 and contact pads 8, the size corresponding to the dimensions of the elements 2; placed on the basis of 1 from the side of the printed conductors 7 on the contact pads elements 2, which are positive 4 and negative 5 electrodes so that the positive 4 elements 2 are connected to the negative 5 elements 2 according to a certain topological scheme; moreover, the elements are fixed to the pads by soldering or electrically conductive glue.

 An example of performing a galvanic applicator (Fig. 16) with a deep galvanic effect and elements of Figs. 9-12 contains a first elastic base 1, a second elastic base 13, made in the form of dielectric films with a coating metallized on one side, and, on one base 1, on the side metallization placed in random order elements 2 of one sign, for example, positive 4, and on another basis 13 only elements 2 of another sign, for example, negative 5; metallization of both bases 1 and 13 are electrically connected to each other by a flexible conductor 14.

 An example of performing a galvanic applicator with a deep galvanic effect (Fig. 17) with elements 2 of Figs. 9-12 contains an elastic base 1 in the form of a strip of a dielectric film metallized on one side, on the one end of which only positive 4 elements 2 with 3 needles 3 out so that there is an electrical contact between their electrodes 4 and the metallization of the base 1, and at the other end of the base 1 on the same side only the negative 5 elements 2 are also placed with their needles outwards; elements 2 are fixed on the metallization of the base 1 by soldering or an adhesive conductive layer 10 deposited on the base 1 on top of the metallization.

 An example of the implementation of a galvanic applicator in the form of a patch (Fig. 18) contains an elastic film base 1 with needles 3 directly mounted in it, arranged in random order and with an arbitrary step with the tips outward, the electrodes 4 and 5 are made in the form of needles of dissimilar metals, and the base 1 has metallization on the side of the needles 3, closing them between each other, or the electrodes 4 and 5 are made on the whole base 1 in the form of metal layers similar to the individual elements 2 of Fig.2-8; the base 1 may contain an adhesive layer 10 deposited on its surface from the side of the needles 3, possibly also together with the needles.

 The galvanic applicator operates as follows.

 The proposed galvanic applicator (Fig. 1) is laid on the naked body of a person in the appropriate place for therapeutic indications for the Kuznetsov iplikator, with the elastic base 1 outward, and the sides of the elements 2 with the tips of the needles 3 coated, or being positive 4 and negative 5 electrodes directed to surface of the human body. Then, the galvanic applicator base 1 is fixed by known methods at the place of its application, for example, by fixing with a plaster, bandage, adhesive layer 10 of the galvanic applicator, or by applying weights (sandbags), or by the weight of the body (in a lying position), or using special fasteners similar to the prototype device. Depending on the type of procedure; type of disease, as with the application of the prototype device, the patient performs various physical exercises, or is in a stationary relaxed state, up to sleep. In addition to the mechanical action of the galvanic applicator, similarly to the Kuznetsov applicator, loops of weak biocurrent (of the order of 10-150 μA) are formed, caused by potentials between electrodes 4 and 5 (of the order of 100 mV 1.0 V), which are formed when they come into contact with the patient's body. The generator of biopatentials in this case is the patient’s body electrodes system, which is self-regulating and generates current and voltage, the magnitude of which is controlled by the body itself and varies according to its needs. In addition, the biopotentials generated in this way by a galvanic applicator do not differ in nature from the internal biopotentials of human organs and tissues. In this regard, any side effects are completely eliminated, in contrast to known devices using external electrical sources. Despite the fact that the galvanic effect itself is weak, its combination with the mechanical action of the needles, due to significant developed pressures in the tissues adjacent to the tips, stretching the skin, tissue relaxation and other favorable conditions on the tips for the galvanic effect, significantly enhances its effect . This, in turn, enhances the complex effect of the effects of the galvanic applicator and allows reducing the treatment time by 3-5 times in comparison with the known Kuznetsov ippler, which significantly exceeds the simple sum of the effect of the mechanical action of the needles and the galvanic effect. In addition, in the case of using the variant of the galvanic applicator of FIG. 3 with elements from copper, the overall therapeutic effect is further enhanced by a combination with metallotherapy, i.e. with the healing effects of copper discs per se.

 When a galvanic applicator of the general therapeutic type, which is universal, is applied to the skin with the elements of FIGS. 2-6, contours of the current flowing through the tissues of the body do not go beyond the limits of the galvanic applicator elements. The current circuits in this case are closed between each other by positive 4 and negative 5 electrodes located on different needles 3, i.e. between different needles within each element 1. At the same time, varying the topology of inter-needle connections (Figs. 4,5,6) gives a different topology of current paths within each element and allows for more or less coverage of tissues involved in the generation of potentials between a pair of electrodes 4 and 5.

 When a galvanic applicator with a local galvanic effect with the elements of FIG. 7.8 there are contours of biocurrents within the tips of the needles (Fig. 7) or within the surface of the tip of each needle 3 (Fig. 8). In this case, the point areas of body tissues located around the pressed needle 3 are involved in the generation of biopotentials. It is advisable to perform such galvanic applicators with needles 3 of maximum length. The action of a galvanic applicator with a local galvanic effect is not limited to the action only on the skin, since it organizes a contrast electronic exchange and provides a powerful reflex effect involving various systems and organs.

 When applying a galvanic applicator with enhanced galvanic effect according to FIG. 9-14, the contours of the currents arise more extensively, since the distance between the elements 2 and between the needles 3 of the various elements 2 is much greater than the distance between the electrodes 4 and 5 within the same element 2 of the general therapeutic galvanic applicator. The topology of the current circuits is rigidly set in the manufacture of a galvanic applicator by wiring the printed conductors 7 on an elastic base 1 (Fig. 12.14). In this case, the use of the galvanic applicator in Fig. 14 is characterized not only by an increase in current contours, but also by the expansion of cross sections of electronic exchange sections due to the use of separate positive 4 and 5 negative galvanic applicator elements. The galvanic applicator in Fig. 13 allows you to change the topology of inter-needle and inter-element electrical connections, which allows you to more flexibly adapt the device for a specific individual application, taking into account the location of acupuncture points and meridians on a specific body ASTK where overlay. This is done by simply replacing the programmable film 11 with another with a new pattern of printed conductors 7 interconnects. When replacing the programmable film 11, a protective, for example transparent, film 12 covering the adhesive layer 10 of the film 11 is previously removed from it to protect it, and then the film 11 is placed with the adhesive layer 10 on an elastic base 1 on the other hand relative to the elements placed on the base 1 so so that the blunt ends of the needles 3 enter the metallized holes 9 of the contact pads 8 of the film 11, thereby making electrical contact of the needles 3 with the printed conductors 7 of the film 11 and through them with each other.

 The application of a galvanic applicator with a deep galvanic effect (Fig. 15.16) is preferably carried out so that the elastic base 1 with positive 4 elements and the other elastic base 13 or the other end of the elastic base 1 (Fig. 16) with negative 5 elements are on opposite sides of the human body , with needles 3 of the elements 2 directed towards the body, as shown in FIGS. 15, 16, moreover, it is desirable that the surfaces of the elastic substrates 1 overlap completely or partially. In this case, biocurrent paths arise, penetrating parts of the human body from one base to another.

 The galvanic applicator of FIG. 18 are used as described above, in addition, before use, sections of the required sizes and configurations can be cut out from it, depending on the application. When applying a galvanic applicator, it is fixed with an adhesive plaster, or with the help of an adhesive layer 10 deposited on its needle surface (Fig. 18).

 The proposed device, in comparison with the known ones, including the prototype, has the following advantages: a significantly larger therapeutic effect, expressed in the reduction of the procedure time by 3-5 times compared with the Kuznetsov applicator adopted as a prototype due to the introduction of additional elements connected by the proposed manner, and carrying out a comprehensive mechanical, electrophysiological and metallotherapeutic action; perfect harmlessness and the complete absence of any side effects due to the use by the body itself of the influence of autogenerated biocurrents and the formation of a self-regulating system with the patient’s galvanic applicator; - extremely high simplicity of design and manufacturability, which does not require special equipment and ease of mass production; high ease of use, which does not require special qualifications of medical staff, which, combined with the absence of side effects, allows us to recommend the device for individual use at home; the present invention allows its use in various numerous variants and modifications, and also allows you to create on its basis a wide range of therapeutic and preventive devices with its use, such as, for example, vacuum garments, vacuum suits, stove benches, etc.

Claims (11)

 1. A galvanic applicator containing a group of applicator elements in the form of a base with needles arranged on an elastic basis so that all sides of the elements have a gap between them, the value of which is not less than the possible displacement of the skin, characterized in that the elements have positive and negative electrodes, interconnected.  2. The galvanic applicator according to claim 1, characterized in that the positive and negative electrodes are made of electrically conductive materials with different electrochemical potentials and can be placed on each and every applicator element together, or separately positive on some elements, negative on others.  3. The galvanic applicator according to claims 1 and 2, characterized in that the positive and negative electrodes can be made in the form of positive and negative and applicator elements made together with the needles, or in the form of positive and negative needles, or film in the form of positive and negative needles, or film in the form of positive and negative thin layers covering the surface of the applicator elements on the side of the needles together with them, and the positive and negative electrodes can be any one type, or various types in various combinations.  4. The galvanic applicator according to claims 1 to 3, characterized in that the subsequent layer of the film electrode of one sign partially covers the previous layer of the electrode of another sign.  5. The galvanic applicator according to paragraphs. 1 to 4, characterized in that the positive electrode of each iplator element is the element itself, made entirely of copper, and the negative electrode is a layer of electrically conductive material with another electrochemical potential deposited on a part of the surface of the element from the side of the needles together with the corresponding needles.  6. The galvanic applicator according to paragraphs. 1 to 5, characterized in that the electrical connections between the elements are made using an elastic base, which from the location of the elements has metallization, and the latter have electrical contact with it.  7. The galvanic applicator according to claims 1 to 6, characterized in that the metallized elastic base contains printed conductors of interelement connections and contact pads on which the applicator elements are located so that the latter have electrical contacts with contact pads and are fixed to them, for example, by soldering, or with the help of an adhesive layer deposited on the contact pad, in the latter case, the elastic base also contains a protective film located on top of the adhesive layer and removed when placed on it ments.  8. The galvanic applicator according to claims 1 to 5, characterized in that the rear blunt ends of the needles of dissimilar electrically conductive materials protrude by a small amount on the back of the dielectric base of each element through an elastic base, while a removable programmable film with printed conductors of inter-needle and inter-element connections is additionally introduced and contact pads or metallized holes according to the number of needles of all elements, the programmable film being placed on the other side of the elastic base relative to By attaching to the applicator elements located on it so that the blunt ends of the element needles have electrical contact with pads or metallized holes, the removable programmable film can be fixed on an elastic basis, for example using an adhesive layer, and have a protective transparent film located on top of the adhesive layer and removable before the location of the programmable film on an elastic basis.  9. The galvanic applicator according to claims 1 to 7, characterized in that all the elements are interconnected and made integral with the elastic base and together with it represent a thin film-substrate with needles, from which sections of the required sizes and configurations can be cut.  10. The galvanic applicator according to claims 1 to 7, 9, characterized in that on the side of the needles the film-substrate has an adhesive layer.  11. The galvanic applicator according to claims 1 to 10, characterized in that it additionally introduces one or more elastic bases with applicator elements similar to the first (s), and all elastic bases or elements on them are electrically connected, for example, by flexible wires.

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