RU2085223C1 - Galvanoplicator - Google Patents

Abstract

FIELD: technics for physical therapy. SUBSTANCE: invention may be used for treating a series of diseases with indications for acupuncture therapy, controlling pain syndromes, stimulation and prophylactic action, removing fatigue, relaxation, increasing general resistance and immunocorrection, as well as for determining topography of acupuncture points and investigation of live organisms in norm and with pathology. Goal of invention is to improve performance characteristics and widen functional capability of apparatus by way of increasing autonomy of apparatus and providing possibility of automatically dosing action and also of mapping acupuncture points on skin surface. Galvanoplicator operates in the following way. Dielectric substrate 1 covered with negative 2 and positive 3 electrodes in the form of one or a series of couples is placed on patient's skin in the place chosen from therapeutic indications, the two electrodes being directed toward skin and tightly abutting to it. At this moment, the voltage appears on electrodes and generator 6 starts generating electric oscillations. As a result, circuit composed of electrodes 2,3, generator, and patient's body conducts alternating microcurrent and, on electrode 4, one can observe alternating potentials. Upon long operation with patient, negative electrode 2 electrolytically dissolve and, after its complete dissolution, apparatus automatically stops. When apparatus is photographed before electrode 2 is completely dissolved, one can observe electrolytically etched figure, on which one can discern electrically active acupuncture zones. EFFECT: improved performance characteristics of apparatus. 13 cl, 11 dwg

Description

 The invention relates to medical equipment and can be used to treat a number of diseases according to indications for acupuncture therapy, relieve pain syndromes, for stimulating and preventive effects, relieving fatigue, relaxation, increasing general resistance and immunocorrection, as well as for determining the topography of acupuncture points and bioenergetics research living organisms are normal and with pathology.

A device for applicative metal reflexotherapy is known, containing an elastic adhesive substrate with metal disks made of thin foil located on it or in the form of sprayed metal films, the disks can be connected with conductive jumpers; the adhesive backing of the discs is coated with an airtight protective film [1]
The known device has a high degree of autonomy and high performance, however, its disadvantages are the low therapeutic effect of exposure and functionality, because the potentials arising on the disks are constant, in addition, there is no possibility of automatic dosing and exposure and determining the position of the cutaneous projections of biologically active zones.

Closest to the proposed device is a bioenergetic effect on acupuncture systems containing a pair of electrodes of dissimilar conductive materials with possibly more different electrochemical potentials, one of which is positive and the other negative, and an electric oscillator, for example, sinusoidal or pulsed, positive and Negative power buses are connected to the positive and negative electrodes, respectively [2]
The known device allows for exposure to alternating or pulsed, generated by the body itself without external energy source currents.

 The disadvantages of the known device are low operational and functional capabilities due to the impossibility of automatic dosing of exposure, low degree of autonomy, because the device is an electrode system connected by wires to the generator, and also because the known device does not allow to determine the localization of the skin projections of acupuncture points, in particular their relative position.

 The aim of the invention is to improve performance and expand the functionality by increasing the degree of autonomy of the device and the possibility of automatic dosing of exposure, as well as mapping the location of acupuncture points on the surface of the skin.

 This goal is achieved by the fact that in the known device for bioenergy exposure of acupuncture systems, at least one electrode is made flexible in the form of a thin film sprayed onto a dielectric substrate, for example, an adhesive film, on one side thereof. In addition, the generator is placed directly on the dielectric substrate. In addition, the generator is made in the form of a capsule mounted in a dielectric substrate, and the surface of the capsule from the side of the sprayed electrode can serve as a second electrode. In addition, the generator is made in the form of a film printed circuit deposited on a dielectric substrate from the side of the electrodes or from the opposite side. In addition, on the same dielectric substrate there is the required number of pairs of electrodes arranged in the necessary order and forming cells connected to the power buses of one generator. In addition, generators were additionally introduced according to the number of pairs of electrodes placed on the dielectric substrate, each cell of a pair of electrodes being connected to the supply lines of its generator and not connected to other cells. In addition, the electrodes are multilayer in the form of conductive layers deposited on each other. In addition, the conductive layers are dyed in different colors of the additive of the corresponding conductive dyes, and the conductive layers of one electrode are made of the same type of material, or of dissimilar materials with different electrochemical potentials. In addition, the alternation of the conductive layers of the two electrodes in a pair is consistent at least with each other and is determined by the program of action of this pair. In addition, the alternation of conductive layers in one cell with a paired electrode is consistent with the alternation of layers in other cells and is determined by the general program of exposure. In addition, the dielectric substrate on the side of the electrodes is covered with a protective thin transparent film attached to the adhesive layer of the dielectric substrate and removed immediately before use. In addition, the generator is made in the form of additional conductive thin film layers sprayed on top of each electrode, and all layers of one electrode have electrical contact with the layers of the other electrode. In addition, the electrochemical potentials of each pair of layers on the positive and negative electrodes are different between the pairs and between each other in each pair of the corresponding layers.

 In FIG. 1 shows a galvanic applicator with a film negative electrode, general view; figure 2 an example of the implementation of the galvanic applicator with a generator located on the reverse side of the rectangular substrate; figure 3 is an example of a plating with a generator in the form of a capsule, which is one electrode; figure 4 an example of the implementation of the plating with the location of the printed circuit of the generator from the side of the electrodes and its view from the back of the substrate; figure 5 an example of the implementation of the plating with the location of the printed circuit of the generator on the back side of the substrate, view from the side of the electrodes; in Fig.6 galvanic applicator in Fig.5, a view from the back of the substrate; in FIG. 7 example implementation of the generator to the circuit diagram; in FIG. 8 is an example of performing a galvanic applicator with several independent pairs of electrodes on one substrate; Fig.9 multilayer electrodes, section; in FIG. 10 diagram of the inclusion of generators; figure 11 is a multilayer plating, section.

 The galvanic applicator (Fig. 1) contains a dielectric substrate 1 with a film consumable negative electrode 2 deposited on it, a positive non-consumable electrode 3, a dielectric substrate 1 at the edges in places free of electrode 2 on the working side, has an adhesive layer 4, an oscillation generator 5 , negative 6 and positive 7 of the power bus which is connected by wires 8 and 9, respectively, with electrodes 2 and 3.

 The galvanic applicator (Figs. 2 and 3) contains a dielectric substrate 1, for example, of a rectangular (Fig. 2) or round (Fig. 3) shape with a film of negative 2 consumable and positive 3 non-consumable electrodes deposited on it; the generator 5 of electrical vibrations is located on the reverse side of the substrate 1 (figure 2) or is made in the form of a capsule mounted directly into the substrate (figure 3), in this case, the lower part of the housing of the generator 5 can serve as a non-consumable positive electrode 3; the negative 6 and positive 7 power supply bus of the generator 5 are directly connected to the negative and positive electrodes, respectively.

 The galvanic applicator (Fig. 4-6) can be made in the form of a patch containing a dielectric substrate 1 with a sprayed film negative 2 and positive 3 electrodes and with an adhesive layer 4 on free spots on the working surface of the substrate 1; the generator 5, made in the form of a printed circuit, for example, by etching part of the film of a positive 3 electrode (figure 4); negative 6 and positive 7 power bus generator 5 are directly connected to the electrodes 2 and 3; the generator 5 (Fig. 7) contains an inductor 10, a resistor 11, a capacitor 12 made in the form of thin films, and a transistor 13 and can be located both from the side of the electrodes 2 and 3, and from the back of the dielectric substrate 1 (Fig. 5 and 6).

 An example of the implementation of the galvanic applicator (Fig. 8) with independent galvanic couples contains a dielectric substrate 1 with deposited pairs of negative 2 and positive 3 electrodes, sized and arranged in accordance with the required topological scheme, with an adhesive layer 4 and generators 5 located on the back side of the substrate 1 or from the side of electrodes 2 and 3 and connecting each pair of electrodes 2 and 3 with their power buses 6 and 7.

A galvanic applicator with multilayer electrodes (Fig. 9) contains a substrate 1 with conductive layers deposited on it, forming electrodes 2 and 3, into which material a dye can be added, and the layers making up electrode 2 can have one identical, for example, negative electrochemical potential, and the layers constituting the electrode 3, the same, but different electrochemical potential, for example positive; the substrate 1 has an adhesive layer 4, on the reverse side, for example, a film generator 5 can be applied, the power lines 6 and 7 of which are connected by jumpers 8 and 9 with the corresponding multilayer electrodes 2 and 3; the electrochemical potentials of the layers of electrodes 2 and 3 can differ not only in pairs, but also between pairs, for example, for layers 14, 16 of electrode 2 and layers 15, 17 of electrode 3 as follows: Φ ₁₄ <Φ ₁₅ <Φ ₁₆ <Φ ₁₇ <.. .. <Φ _n-1 <Φ _n in this case, on the dielectric substrate 1, for example, on the reverse side there is a second generator 18, similar to the first generator 5, the positive 19 and negative 20 power buses of which are connected respectively to the negative 6 and positive 7 buses the first generator 5, either directly or through a dividing unpacked diode s 21 and 22 (figure 10).

Гальванопликатор (фиг.1-7) работает следующим образом.The galvanic applicator (Fig. 11) with a low-frequency generator, made in the form of short-circuited multilayer electrodes, contains a dielectric substrate 1 with electrodes 2 and 3 and an adhesive layer 4, and the electrodes 2 and 3 are thin metal films deposited on a substrate 1, for example, with overlapping, the electrochemical potential of all layers 14, 16 and other electrode 2 and 15, 17 and other electrode 3 differ from each other as

The galvanic applicator (Fig.1-7) works as follows.

 The dielectric substrate 1 coated with a negative 2 electrode (Fig. 1) or one or more pairs of 2 negative and positive 3 electrodes (Fig. 2-7) is placed on the skin of the patient in the right place for therapeutic indications, for example, for reflexology [ 3] and the electrodes should be directed to the skin of the patient and fit snugly to it. Adhering to the skin is carried out using an adhesive plaster or an adhesive layer 4 applied to the dielectric substrate 1 from the side of the electrodes 2 and 3. At the same time, voltage appears on the electrodes 2 and 3 and the generator 5 starts to generate electrical vibrations, and the electrode 2 generator 5 along the circuit 2. the patient's body begins to flow alternating, including pulsed, microcurrent. The voltage at the electrodes 2 and 3 is also variable and, similarly to the prototype device, has a therapeutic effect on the patient's body reflexively through the skin, deep structures and biologically active points.

 Since the electrodes are sprayed thin conductive layers, the electrolytic dissolution of the negative electrode 2 (positive electrode 3 is insoluble) can significantly affect the state of its conductive layer. In particular, by varying its thickness, it is possible to produce electrodes with a programmed exposure time until the conductive layer of the negative electrode 2 is completely dissolved, which leads to an automatic deviation of the device after a specified time. This makes it possible to simplify the dosage of exposure and operation of devices installed simultaneously on different parts of the body of one patient, or simultaneously on several patients, because there is no need to track the exposure time of each device.

 In addition, the implementation of the generator 5 in the form of a printed circuit (Fig.4-6) located on the back side of the dielectric substrate 1 relative to the electrodes 2 and 3, can significantly increase the operational convenience of the device, especially in the case of the simultaneous use of several devices located in different areas the patient’s body, because in this case the galvanic applicator looks like an ordinary patch.

 If the device is interrupted before it is automatically turned off, i.e., until the negative electrode 2 is completely dissolved in the form of a sprayed layer, then due to its small thickness, its electrolytic dissolution under the action of a current flowing through the circuit through electrodes 2 and 3, generator 5 and the patient’s body leaves an etched pattern on it, corresponding to the heterogeneities of the electrical structure of the skin. Since biologically active acupuncture points (BAPs) create the greatest electrical heterogeneity, a pattern is formed on the negative 2 film electrode in which it is possible to distinguish according to the location of the BAT on the patient’s skin area covered by it. This allows you to use the device also to find the individual location of the BAT acupuncture and their mapping, i.e. relative positioning relative to each other, which greatly facilitates this procedure and expands the functionality of the device.

 The execution of several pairs of electrodes 2 and 3 on the same substrate 1 with separate generators 5 for each pair (Fig. 8) allows you to create several independent current circuits flowing in the appropriate places through the patient’s body when the device is applied, as well as implement different exposure modes of each pair for example, different frequencies at the same time.

 The execution of the negative electrode 2 as a multilayer one, consisting of identical layers with the same electrochemical potentials, but with the addition of conductive dyes so that each layer has its own color, allows you to get a more clear three-dimensional picture of the potential relief of the BAP on the skin surface, since the depth of etching of the electrode 2 is proportional to potential, encoded in this case in a specific color. In this case, it is also very easy to determine equipotential surfaces having the same color on the cartogram.

(фиг.8), то при включении устройства, т. е. при его размещении на пациенте, происходит генерация электрических колебаний генератором 5 и электролитическое растворение верхнего непосредственно прилегающего к коже слоя 14 электрода 2, электрохимический потенциал которого меньше другого прилегающего слоя 15 электрода 3. После его растворения под ним открывается следующий слой 16, электрохимический потенциал которого больше потенциала слоя 15, в результате чего последний становится отрицательным относительно слоя 16 и, в свою очередь, начинает растворяться, т.е. происходит переключение полярности электродов 2 и 3, а генерация электрических колебаний осуществляется вторым генератором 18 от этих электродов через его шины питания 19 и 20 (фиг. 9 и 10). После растворения слоя 15 под ним открывается следующи слой 17, потенциал которого больше потенциала слоя 16, последний становится отрицательным и происходит его растворение, генератор 18 выключается, а генератор 5 включается снова и т. д. Таким образом, подбирая толщину и количество слоев, можно задавать программу автоматической смены полярности электродов через заданные промежутки, что улучшает эксплуатационные возможности устройства, поскольку исключает процедуру ручной смены полярности электродов и повышает тем самым терапевтический эффект, поскольку ввиду постоянной смены полярности электродов снижается адаптируемость организма к воздействию. В случае расположения нескольких пар многослойных электродов 2 и 3 на одной подложке 1 (фиг.8) подбором числа и толщины слоев можно задавать программу согласованной смены полярности электродов 2 и 3 во времени и пространстве заданной топологии при лечебном воздействии.If the electrochemical potentials of the layers of multilayer electrodes are different, so

(Fig. 8), when the device is turned on, that is, when it is placed on the patient, electrical oscillations are generated by the generator 5 and the electrolytic dissolution of the upper layer 14 of the electrode 2 immediately adjacent to the skin, the electrochemical potential of which is less than the other adjacent layer 15 of the electrode 3 After its dissolution, the next layer 16 opens under it, the electrochemical potential of which is greater than the potential of layer 15, as a result of which the latter becomes negative relative to layer 16 and, in turn, begins to dissolve be created, i.e. the polarity of the electrodes 2 and 3 is switched, and the generation of electrical oscillations is carried out by the second generator 18 from these electrodes through its power bus 19 and 20 (Figs. 9 and 10). After dissolution of the layer 15, the following layer 17 opens under it, the potential of which is greater than the potential of the layer 16, the latter becomes negative and dissolves, the generator 18 turns off, and the generator 5 turns on again, etc. Thus, choosing the thickness and number of layers, you can set the program for automatically changing the polarity of the electrodes at predetermined intervals, which improves the operational capabilities of the device, since it eliminates the procedure for manual changing the polarity of the electrodes and thereby increases the therapeutic ffekt, since because of the constant change of polarity of the electrodes is reduced adaptability of the organism to the action. If several pairs of multilayer electrodes 2 and 3 are located on the same substrate 1 (Fig. 8) by selecting the number and thickness of the layers, you can set the program for a coordinated change in the polarity of the electrodes 2 and 3 in time and space of a given topology during therapeutic treatment.

 The generator 5 can also be implemented as multilayer electrodes 2 and 3, if their layers are directly connected electrically (Fig. 11). In this case, the variable nature of the effect is ensured by changing the polarity of the switched electrodes by electrolytic dissolution of the layers. The frequency of exposure in this case is determined by the frequency of switching the polarity of the electrodes 2 and 3 and is determined by the thickness of the deposited layers and can lie in the range of 0.1-10 Hz. The layers of electrodes 2 and 3 can be made of metal alloys, and the magnitude of the electrochemical potentials is determined by the concentration of the components of the alloy of the materials of the electrodes.

 The generators 5 and 18 are identical and can be implemented according to the circuit shown in Fig.7. Each generator contains an inductor 10, a resonator 11, a capacitor 12, sputtered on a dielectric substrate 1 of thin metal films, and a transistor-free transistor 13 (Fig.7). From above, the generator circuit can be coated with an airtight protective film glued to the dielectric substrate 1, or with a dielectric protective varnish. The oscillator circuit of the generator can be designed for a frequency of generation in the range of 10 kHz 1.5 MHz.

The present invention has the following advantages compared with known devices, including the prototype:
significantly higher operational capabilities due to increased autonomy and ease of use due to the implementation of the device in the proposed manner, since it looks like a conventional patch;
the possibility of therapeutic use of the device continuously for a long time;
increased infectious protection, as the device can be made disposable;
high manufacturability and simplicity, which allow mass production of devices to be launched with minimal costs;
ease of use, which does not require special training and allows you to recommend the device for widespread use, up to individual use at home;
the absence of the need to control the device in the process of its application, which especially expands the operational capabilities while using several devices located on the same patient or on several patients;
significantly wider functionality, as allows you to automatically dose the impact and program the switching of the polarity of the electrodes;
the implementation of the ability to determine the relative position of acupuncture zones with the ability to map them automatically, which also extends the functionality of the device and allows its use for diagnostic purposes.

Claims (13)

 1. A galvanic applicator containing a pair of electrodes made of dissimilar electrically conductive materials with possibly different electrochemical potentials, one of which is positive and the other negative, and an electric oscillator, for example, sinusoidal or pulsed, the positive and negative power lines of which are connected to the positive and negative electrodes, respectively characterized in that at least one electrode is made flexible in the form of a thin film deposited on a dielectric base Ku, e.g. adhesive film on one side thereof.  2. The galvanic applicator according to claim 1, characterized in that the generator is placed directly on the dielectric substrate.  3. Electroplating on PP. 1 and 2, characterized in that the generator is made in the form of a capsule mounted in a dielectric substrate, and the surface of the capsule on the side of the sprayed electrode can serve as a second electrode.  4. Electroplating on PP. 1 and 2, characterized in that the generator is made in the form of a film printed circuit deposited on a dielectric substrate from the side of the electrodes or from the opposite side.  5. Electroplating according to paragraphs. 1 to 4, characterized in that on the same dielectric substrate, the required number of pairs of electrodes is installed, arranged in the necessary order and forming cells connected to the power buses of one generator.  6. Electroplating on PP. 1 to 5, characterized in that the generators are additionally introduced according to the number of pairs placed on the dielectric substrate of the electrodes, each cell of the electrode pair being connected to the supply lines of its generator and not connected to other cells.  7. Electroplating on PP. 1 to 6, characterized in that the electrodes are multilayer in the form of conductive layers deposited on each other.  8. Electroplating on PP. 1 to 7, characterized in that the conductive layers are colored in various colors by additives of the corresponding conductive dyes, and the conductive layers of one electrode are made of the same type of material or of dissimilar materials with different electrochemical potentials.  9. Electroplating according to paragraphs. 1 to 8, characterized in that the alternation of the conductive layers of the two electrodes in a pair agreed at least among themselves and determined by the program of action of this pair.  10. Electroplating according to paragraphs. 1 to 9, characterized in that the alternation of conductive layers in one cell of the pair of electrodes is consistent with the alternation of layers in other cells and is determined by the General program of exposure.  11. Electroplating according to paragraphs. 1 to 10, characterized in that the dielectric substrate on the side of the electrodes is covered with a protective thin film glued to the adhesive layer of the dielectric substrate and removed immediately before use.  12. Electroplating according to paragraphs. 1 to 11, characterized in that the generator is made in the form of additionally introduced conductive thin film layers sprayed on top of each electrode, and all layers of one electrode have electrical contact with the layers of the other electrode.  13. The galvanic applicator according to claims 1, 2 and 12, characterized in that the electrochemical potentials of each pair of layers on the positive and negative electrodes are different between the pairs and between each other in each pair of the corresponding layers.

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