WO2022203526A1 - Resonant and ergonomic bioelectric device for self-generating potential differential with antiviral copper and magnesium ion injection - Google Patents

Abstract

The present invention relates to a resonant and ergonomic bioelectric device for self-generating potential differential with antiviral copper and magnesium ion injection, for producing a progressive microcurrent, of the type comprising a main body, a conductive network, a resonant unit, a function selector, a resistor circuit, and an adjustment element, characterised in that the main body consists of a magnesium-aluminium alloy plate or similar, a galvanised iron plate or similar, and a copper plate, which are arranged on an insulating layer; and a user-adaptable adjustment element consisting of an elastic band attached to a male velcro fastener and a female velcro fastener.

Description

RESONANT AND ERGONOMIC BIOELECTRIC DEVICE FOR SELF-GENERATION OF POTENTIAL DIFFERENTIAL WITH ANTIVIRAL IONIC INJECTION OF COPPER AND MAGNESIUM

TECHNICAL FIELD

The following invention is developed in the field dedicated to the manufacture of electrical stimulation devices, specifically devices for the application of microcurrents.

BACKGROUND OF THE INVENTION

Electrical stimulation electrotherapy devices for alleviating or eliminating pain are currently known, which apply electrical current directly to the human body. In addition, there is the certainty of the antiviral properties of the elements copper and magnesium.

Known devices that use microcurrents for electrotherapy have several limitations, such as:

- they need power supplies or batteries for their operation;

- when using battery or power supplies, they apply to the human body a voltage in volts in the form of a step input, producing a microcurrent also in the form of a step input;

- when applying a voltage in volts as a step input, they cause sensitivity discomfort to the user due to the direct application of microcurrents.

- They lack, among their components, ion injection plates.

- They need security systems to control failures that could occur with the user and;

- It is used in people in a fixed and static horizontal position with specialized personnel for their supervision.

Document ES 2296809T3 describes a device for generating current, called a current production generator for electrode sheaths through copper wire and a method that comprises the application of microcurrents for electrotherapy, which receives electrical power from a drums. The application of microcurrent through said device is in the form of a jump or step, causing discomfort to the user. Likewise, the document ES 2635517T3 describes a device to control pain using microcurrent electrical therapy using electrodes, the design of the device guarantees electrical safety through the use of 1.5 volt batteries. On the other hand, document ES 2332989T3 describes a microcurrent therapeutic device directed to an electronic stack located in a therapeutic device in electrical connection with the user's skin, it uses a button battery inside the electronic stack.

The devices mentioned above have the drawback that they apply microcurrents in the form of a jump or step by means of cells or batteries, causing sensitivity discomfort to the user due to the direct application of microcurrents.

DESCRIPTION OF THE INVENTION

As a solution to the aforementioned problems, the present invention called "Resonant and ergonomic bioelectric device for self-generation of potential differential with antiviral ionic injection of copper and magnesium" was developed, which consists of a device adaptable to the user and allows the self-generation of a potential differential with ionic injection of copper and magnesium in two modes, without resonance and with resonance, to produce a progressive microcurrent, where said device comprises a main body, which contains on its surface an insulating sheet where three plates are located, of which one plate is made of galvanized iron located in the center and two plates of which one plate is made of aluminum-magnesium alloy and the other is made of copper; the plates are arranged parallel to each other, said plates are connected with conductors, two being copper and one galvanized iron; these conductors are connected to the resistor, so that one end of the first resistor is connected to the copper conductor and the other end is connected to the first galvanized iron conductor, in the same way one end of the second resistor is connected to the conductor copper and the other end connects with the second galvanized iron conductor. Also, a resonant unit comprises a first and second resonant circuit, it receives the energy from the human body and converts it into a potential differential that is connected by a function selector to the first and second resistors, this potential differential produced is added to the differential of previously produced potential. The full potential differential produced by the resonant bioelectric device is applied to the resistor circuit.

The main body is made up of a galvanized iron plate located in the center and two plates at the ends, of which one plate is made of aluminum-magnesium alloy and the other is made of copper; the plates are arranged parallel to each other, which are on an insulating sheet together forming a single block. The free part of the insulating sheet has a cover, which is on the opposite side where the plates are arranged in parallel.

The conductor is specifically made up of a negatively charged conductor of galvanized iron, a first and a second positively charged conductor of copper, these are arranged in parallel. The galvanized iron conductor is connected to the galvanized iron plate, and the first and second copper conductors are connected to the aluminum magnesium alloy plate and the copper plate respectively; these conductors receive the potential differential and produce a double microcurrent flow through the galvanized iron plate as a common point.

The resonant unit is made up of a first and a second resonant circuit, and each resonant circuit has elements such as the inductor, the capacitor and the resistor; where finally, the resonant unit is connected to the resistor circuit.

The function selector allows the device to operate in two modes, such as: the self-generation of potential differential without resonance, and the self-generation of potential differential with resonance. The resistor circuit is specifically made up of the first and second resistors with their respective ends, where the first resistor connects one end with the copper conductor and the other end connects with the galvanized iron conductor, in the same way, the second resistor connects one end with the same galvanized iron conductor and the other end connects with the second copper conductor.

An adjustment element attached to the main body has a first elastic band with a male velcro closure located at one end, and a second elastic band with a female velcro closure located at the other end.

The present invention describes a device that allows self-generation of a potential differential with ionic injection of copper and magnesium in two modes of operation: without resonance and with resonance; to produce a microcurrent that increases progressively and naturally so as not to cause damage or discomfort to the user. In addition, said device is ergonomic since it allows, through the adjustment element, to be able to adapt to the user.

BRIEF DESCRIPTION OF THE FIGURES

To complement the description that is being made and with the aim of helping a better understanding of the characteristics of the invention, a set of figures is attached where the following has been represented for illustrative and non-limiting purposes:

Figure 1: A perspective view of the proposed invention is shown where the main body, a conductive network, a resonant unit, a function selector, a resistor circuit and the adjustment element can be seen.

Figure 2: The device adaptable to the user is shown, taking as an example covering the human body's back and abdomen. Figure 3: Shows the wiring diagram of the electrical elements of the resonant and ergonomic bioelectric device for self-generation of potential differential with ionic injection of copper and magnesium.

Figure 4: The process block diagram of the resonant and ergonomic bioelectric device for self-generation of potential differential with ionic injection of copper and magnesium is shown.

Figure 5: The graph of voltage versus time and the graph of microcurrent versus time of the process in non-resonance potential differential self-generation mode are shown.

Figure 6: The graph of voltage versus time and the graph of microcurrent versus time of the process in autogeneration mode of potential differential with resonance are shown.

The figures that accompany this descriptive report contain numerical references to the elements that make up the invention and that correspond to the following:

1 main body

11 aluminum magnesium alloy plate

12 galvanized iron plate

13 copper plate

14 insulating foil

15 deck

2 Conductive network

21 first copper positive charge conductor

22 galvanized iron negative charge conductor

23 second copper positive charge conductor

3 Resonant unit

31 first resonant circuit

32 second resonant circuit

4 Function switch

5 Resistor circuit 51 first resistor 52 second resistor 6 Setting element

61 first elastic tape

62 second elastic band

63 male velcro closure

64 female velcro closure

PREFERRED EMBODIMENTS OF THE INVENTION

As can be seen in the attached figures, the invention consists of a main body (1), a conductive network (2), a resonant unit (3), a function selector (4), a resistor circuit (5), and an adjustment element (6). Where the main body (1) is made up of an aluminum magnesium alloy plate (11), a galvanized iron plate (12) and a copper plate (13), which are on an insulating sheet (14) together forming a single block. The free part of the insulating sheet (14) has a cover (15).

In the example shown, the main components of the invention are presented, such as the main body (1), conductive network (2), resonant unit (3), function selector (4), resistor circuit (5), and a control element. adjustment (6) that allows the adaptability of the device to the user.

The conductive network (2) is made up of: a negatively charged conductor of galvanized iron (22), and the first and second positively charged conductors of copper (21, 23) in parallel arrangement, with very low resistance. The function selector (4) is basically made up of a switch that allows the resonant unit to be connected to the resistor circuit (5). This resistor circuit (5) is made up of: the first and second high-resistance resistors (51, 52).

In the example shown, the conductive network (2), resonant unit (3), function selector (4) and resistor circuit (5) are in a single unit to optimize spaces, they are also attached to the main body (1 ) corresponding to the side of the cover (15). The invention further comprises an adjustment element (6) with a first elastic band (61) attached to a male velcro closure (63) located at one end, and a second elastic band (62) with a female velcro closure (64). located at the other end.

In the example shown, the adjustment element (6) presents its use and adaptability to the user, where the plates of the main body (11, 12, 13) are horizontally arranged so that they can be placed both on the front side of the body - the back-, and on the reverse side -abdomen.

The electrical components of the invention are: the main body (1), the conductive network (2), the resonant unit (3), the function selector (4), and the resistor circuit (5). These connect forming an electrical circuit with the body surface of the human body.

In the example shown, the connection diagram of the invention is presented, where the total potential difference is applied when the function selector (4), made up of a switch, is in a closed circuit, that is, in resonance mode for this way to circulate a microcurrent that is received by the resistor circuit (5).

Trial

The applicant has carried out the tests using the device according to the invention. The results in said tests are typical of the results of the present invention, which are detailed in figures 5 and 6. The device has been used in a horizontal position in the area of the abdomen of the human body, for which two multimeters were used. calibrated in function voltmeter and ammeter in low scale, in addition to a timer to register the time. The measurement of voltages 1 and voltage 2 corresponds to the first and second resistors (51, 52). In the same way, the measurement of current 1 and 2 corresponds to the first and second resistors (51, 52).

In the example shown, the results of the generated voltage in versus time are presented, through the application of the device in non-resonance mode, observing an increase in an average potential differential from 0 to 700 millivolts to produce an average microcurrent of 0 to 14 microamps that increases progressively or ramps until reaching the stable state in a time of 55 min.

In the example shown, the results of the generated voltage are presented as a function of time, by applying the device in resonance mode, observing an increase in an average potential differential from 0 to 770 millivolts to produce an average microcurrent of 0 to 15 microamperes. that increases progressively or ramps until reaching the stable state in a time of 30 min. In the example, voltage 1 corresponds to the measurement of the voltmeter that connects the positive test lead (red) to the aluminum magnesium alloy plate (11), and the negative test lead (black) that connects to the common point of the galvanized iron plate (12) giving a positive reading of +109 mV, indicating the injection of positive magnesium ions; Likewise, voltage 2 corresponds to the other measurement of the voltmeter that connects the positive test lead (red) to the copper plate (13), and the negative test lead (black) that connects to the common point of the iron plate. galvanized (12) giving a positive reading of +765 mV, indicating the injection of positive copper ions.

Claims

1. An ergonomic resonant bioelectric device for self-generation of potential differential with antiviral ionic injection of copper and magnesium of the type comprising a main body (1), conductive network (2), resonant unit (3), function selector (4 ), resistor circuit (5), and adjustment element (6); characterized because:

- the main body (1) is made up of an aluminum-magnesium alloy plate or similar (11), a galvanized iron plate or similar (12) and a copper plate (13), which are on an insulating sheet (14) forming a single block as a whole, with a cover (15) that covers the free part of the insulating sheet (14);

- the resonant unit (3) is made up of a first and second resonant circuit (31, 32);

- the function selector (4) is made up of a switch that connects to the resistor circuit (5);

- the resistor circuit (5) made up of a first resistor (51) that connects one end with the first positive charge conductor of copper (21) and the other with the negative charge conductor of galvanized iron (22), the same, a second resistor (52) connects one end to the second copper conductor (23) and the other end connects to the galvanized iron negative charge conductor (22); Y

- An adaptable adjustment element consisting of an elastic band (61, 62) attached to a male velcro closure (63) and a female velcro closure (64).

2. A resonant and ergonomic bioelectric device for self-generation of potential differential with ionic injection of copper and magnesium, according to claim 1, characterized in that the conductive network (2) has a negatively charged conductor of galvanized iron (22) is connected to the galvanized iron plate (12) and, the first and second positively charged copper conductors (21 and 23) are connected to the aluminum magnesium alloy plate (11) and the copper plate (13) respectively.