BR102012014555A2 - MAGNETIC FIELD ELECTRONIC CATCH - Google Patents

Abstract

ELECTRON CAPTOR FOR MAGNETIC FIELD. The reference refers to an electromagnetic device that produces a magnetic / electromagnetic field with low consumption of electrical energy supplied from the initial source to the supply of the coil (s) (1 and 2). The current for the formation of the magnetic field is originated through the instantaneous capture of electrons from the earth, which provides an electron current flow through the grounding mesh that is connected to the coils (1 and 2), and there is an endless supply of electrical current without resistances in the conductive link (s) (8 and 9) of the interconnection of the coil (s) (1 and 2), where the electron current starts to move with tension or without tension electrical, a fact that is subject to the way the electrical circuit is connected. With the technical objective of producing a magnetic / electromagnetic field through the capture of electrons that can be used for levitation and / or propulsion of any type of mass that occupies a place in space, among them we highlight, in general, machines, equipment and objects , being fixed or mobile that can be of any size and weight, either through electromagnetic levitation, or magnetic levitation and repulsion, or magnetic attraction levitation, or magnetic induction levitation, or electromagnetic levitation and propulsion, or magnetic levitation and repulsion, or magnetic attraction levitation, or magnetic induction levitation, or electromagnetic levitation and propulsion, by rotation or to form a magnetic field with no voltage current for therapeutic use, medicinal treatment.

Description

Report of the Invention Patent for "ELECTRONIC CAPTOR FOR MAGNETIC FIELD"

The present invention relates to an electromagnetic captor device which produces a low electric field magnetic field supplied from the initial source for the supply of coils (1 and 2), the current being generated and moving in ( (s) (s) (8) and (9) interconnecting conductor (s) of the coil (s) (1 and 2) for magnetic field formation originate from the instantaneous capture of electrons through the grounding loop comprising coil (1) interconnected with other coil (s) (2) or through the combination of coil (s), electromagnet (s), inductor (s) and / or magnet (s) (m) be interconnected by one or more interconnecting conductor link (s) (8) and (9), which in turn shall be interconnected to the grounding loop through the interconnecting conductor member (10) to grounding. Grounding may be replaced by an isolated core or any other type of conductive element that performs the grounding function or any other source that releases and remains negatively charged that can supply electrons through electromagnetism for magnetic field formation through the grounding force. electromagnetic attraction and repulsion with a potential difference, for the technical purpose of producing magnetic / electromagnetic fields - through electron capture - to be used for levitation and / or propulsion of any mass occupying a place in space, including we generally highlight machines, equipment and objects, whether fixed or mobile and of any size and weight, whether by electromagnetic levitation, magnetic levitation and repulsion, magnetic attraction levitation, or magnetic induction levitation, or levitation and electromagnetic propulsion by route or will magnetic field formation with current without the voltage for therapeutic use, medical treatment. The captors can be single phase, two phase or three phase, with the purpose of capturing electric current for the formation of electromagnetic field with voltage or without electric voltage.

Coils 1 and 2 may also be superconducting 5 coils constructed of any anatomical, geometric or silicon iron coil or any other suitable metal pg. (2) fig. (1), (2) and (3). The term "coil" as used herein means accommodating conductors coiled in insulated silicon iron frame with several blades one above the other, can be constructed in a rounded shape (7) fig. (6), square with columns (7) fig. (4) or without column, “window” (7) fig. (5). The construction of the round-shaped coils (4), (1) and (2) must be completely insulated with insulating material according to their single phase, two phase or three phase phases; the constructive form of the square coil without column p. (7), Fig. (5) 15 must be completely insulated with insulating material, according to their single-phase, two-phase or three-phase phases and the constructive shape of the square central column coil. (1), (2) and (3) Only the central column with insulating material shall be isolated according to its single phase, two phase or three phase phases.

Coil (s) (1) and (2) may be at least one

nucleus, and may have more nuclei, which may be of any anatomical, geometric shape; of silicon iron or any other suitable metal, with column (s) or without columns and the core (s) being formed of at least one or more number (s) of limb (s) ) 25 connected by breeches, which together form one or more core windows.

Primary coil winding should be done with enameled conductive members of copper or any other suitable metal, or using appropriate superconducting wires or cables, and the cross section should be sized to the desired coil (s) voltage and current. ) (1 and 2). Coils (1 and 2) may be powered at low, medium or high voltage and the interconnecting conductor link (s) (8 and 9) may be supplied at the same voltage as coils ( 1 and 2) or the interconnecting conductor link (s) (8 and 9) of the coil (s) (1 and 2) can be powered, polarized with the voltage from another source, and this voltage may be different, less than or greater than the supply voltage of coil (s) (1 and 2).

The core (s) of the coil (s) are formed of oriented silicon iron laminated sheets and the core is formed of a certain number of members (legs) connected by breeches, which together form one or more windows. core, coils having such a core are called core coils, around at least one interconnecting conductor link (8 and 9) with at least one loop wound around the first coil (1) is inserted around the core of the coil. and at least two turns winding the coil (2) and the other coils, being able to take more turns in each coil, this winding and number of turns are directly related to the amount of current to be captured and the temperature with the electromagnetic field, effect. It starts from the interconnection between the coils (1 and 2) and is formed on the interconnecting conductive link (8 and 9) between the coil cores, thus, the connection between the cores is realized.

The connection of the captor to the grounding loop shall be made with a bare or insulated conductor member (10) of copper or any other suitable metal which may be of any anatomical and / or geometrical composition and shape, turning in a “ and positioning it close to the interconnecting conductor link (8 and 9) of the coils (1 and 2), preferably close to the coil (s), this connection of the captor to the grounding loop can also be made, without the use of the knot, by approach or through connectors, terminals, solder, busbars or any other type of connection, the other end of the conductive member (10) must be interconnected to the grounding loop. If this grounding loop is replaced by any other type of conducting element that performs the grounding function, the neutral cannot replace the grounding when the conductive member (10) is positively charged, and when the coils (1 and 2) are negatively charged the neutral will become positive when the coils (1 and 2) are positively charged the neutral will become negative again. Grounding may be replaced by single core pickups or any other type of 10-current conductive element that performs the negatively charged grounding function that conducts and releases electrons.

Feeding the coils (1 and 2) with voltage initiates the capture of electrons and the formation of the magnetic / electromagnetic field through the formation of the electron flux that becomes 15 then the formation of the electric current in the link (s). The interconnecting conductor (s) (8 and 9) of the coil (s) (1 and 2), which moves north and south, the appearance of the magnetic, electromagnetic field with other types of devices that induce current through the magnetic field appearing on the interconnecting conductor link (s) (8 and 9) through the grounding conductor interconnecting conductor member (10), or replacing the grounding with the closing of the coil core, insulated core.

The Captor captures alternating or continuous AC / DC electrical current from 0.1 OA to thousands of hundreds of KA or more than 1000 MA 25 and its amperage may be less than or greater than that, the conductor link (s) ) (8 and 9) of interconnection of coil (s) (1 and 2) can be biased with voltage different or equal to the voltage of coil (s) (1 and 2) at any voltage from 0.10 V to thousands of hundreds of KV or more than 1000 MV, and the voltage of the coil (s) interconnecting conductor (s) (8 and 9) may be ) (1 and 2) be different from the voltage (s) of the coil (s) (1 and 2), greater than or less than that voltage (s).

The coil (1) or the coil (2) may be replaced by superconducting electromagnets or superconducting inductors or superconducting magnets regardless of the amount to be used, depending on the size of the link pickup circuit ( conductor (s) (8 and 9) of interconnection of coil (s) (1 and 2).

The sensor can have two more coils (1 and 2), can have up to tens, hundreds or thousands of coils interconnecting the closure 10 of the magnetic / electromagnetic circuit, where the current moves in the circle formed by the link (s). conductor (s) (8 and 9) depending on the length of the interconnecting conductor link (s) (8 and 9) of the coil (s) (1 and 2), the length of the The connecting link (s) (8 and 9) may be from 100 cm to 100,000 km, according to the purpose and need of the circuit, and the distance may be less than or greater than these measurements, and its constructive, anatomical, geometrical form may be of any shape during the course of the circuit (s) of the interconnecting conductor link (s) (8 and 9).

The interconnecting conductor link (s) (8 and 9) may also consist of superconducting wires or cables and the coil (s) (1 and 2) may (m) have at least one or more than one interconnecting link (8 and 9), and may have up to tens, hundreds or hundreds of thousands of interconnecting link (s) (8 and 9) surrounding and interconnecting ( s) coil (s) (1 and 2).

Electron Pickups for Magnetic Field must

be protected, installed inside closed or open box or without box, and can be any type and shape of enclosure (box) of any kind of protective material, always obeying the technical norms that refer to the degree of protection of the electrical equipment, as the environment and supply and collection voltage to be used, for use in aerial installations, above ground, underground, submerged for indoor or outdoor use.

Pickups can be any power from 1 VA to 1000

MVA, single phase, two phase or three phase, and their power may be less than or greater than these powers.

In the interconnecting conductor link (s) (8 and 9) of the coil (s) (1 and 2) the magnetic field originates through the electromagnetic force that generates the movement of electrons without electrical voltage. .

There is no drop in electron capture if the voltage is

keep stable.

DESCRIPTION OF TECHNICAL STATE

As is known in the art according to Lenz's Law, any induced current has a sense such that the magnetic field it generates opposes the variation of the magnetic flux that produced it. Mathematically, Lenz's Law is expressed by the negative (-) sign that appears in the form of Faraday's Law.

According to Faraday's Law, if the flux of the magnetic field across the surface bounded by a circuit varies over time, an induced electromotive force (emf) appears in this circuit. Mathematically to understand: ε = -ΔΦ / Δί

As examples of applying Faraday's Law they will calculate the induced emf in a rectangular loop that moves in or out at a constant velocity from a uniform magnetic field region as per p. n ° 8/8 (fig.1) the flux of the magnetic field across the boundary-bounded surface valley d> = xLB and its variation in time, AO / At = (Ax / At) LB = vLB. So: ε = ν ! _Β and if the loop has a resistance (R) the induced current is: i = ε / R = vLB / R.

A conductor traversed by an electric current dipped in a magnetic field is under the action of a force given by F = IL x B. Thus, by the effect of the induced current in the loop, appear the forces Fi, F2 and Fm. As illustrated on p. 8/8 (fig.1), the first two cancel each other out; The third is canceled by an external force necessary to keep the loop at constant speed.

Since the force Fm must be opposed to the force Fext, the current induced in the loop by varying the magnetic flux must have the indicated direction, p. 8/8 (fig.1) this fact constitutes a particular example of Lenz's Law.

Let us consider in the context of the experimental activities discussed with Faraday's Law when a magnet is approached from a coil the induced current in the coil has a given sense, thus generating a magnetic field whose north pole confronts the north pole of the magnet.

The two poles repel each other, that is, the field generated by the induced current opposes the movement of the magnet. When the magnet is moved away from the loop, the induced current is counter-indicated because, thus, it generates a magnetic field, whose south pole faces the north pole of the magnet, the two poles attract each other, that is, the field generated by the magnet. induced current is opposed to the move away from the magnet. This is the famous and undesirable engine brake on current generators.

When two coils are placed face to face there is no current in either of them, the moment the switch is closed a current appears in the corresponding coil, then an induced current appears in the second coil. When the key is closed, the corresponding coil current goes from 0 to the maximum value which thereafter remains constant.

So while the current is changing the field it generates, the north pole confronting the second coil is also changing, and so is the flow of this field through this second coil, so an induced current appears in the second coil whose direction It is such that the field it generates tends to decrease the flow mentioned, that is, it presents the north pole confronting the north pole of the first coil field.

When the key is opened the current in the first coil goes from the maximum given value up to 0, the current field decreases and the flow of this field in the second coil also decreases so that the induced current is now in the opposite direction, which is such that field that the induced current generates adds to that one, that is, it presents a south pole confronting the north pole of that field. The fact expressed in Lenz's Law that any induced current has the effect that opposes the cause that produced it, is an embodiment in this context of the principle of energy conversion.

If the induced current acts to favor the variation of the magnetic flux that produced it, the coil's magnetic field would have a south pole confronting the north pole of the magnet that approaches the magnet to be drawn towards the coil.

If the magnet were then abandoned it would be accelerated towards the coil by increasing the intensity of the induced current, which would generate an ever larger field that would in turn attract the magnet with ever increasing force, and so on with increasing increase in magnet kinetic energy. If the energy of the magnet system were to be withdrawn at the same rate as the magnet's kinetic energy increases, there would be an endless supply of energy, we would have a perpetual motor that would violate the principle of energy conservation, so we can deduce that generators today cause a great loss of other forms of energy, eg (mechanical, fueled, combustion engines), (coal-fired thermoelectric power to produce steam (CV)), (hydroelectric fueled by large water reservoirs), (nuclear fueled by enriched uranium to produce steam (CV)).

In accordance with the present inversion we created the possibility of energy capture through the magnetic field generated by the induced current in the cores of the electron pickup coils, thus originating the electric current induced through the earth by the grounding wire cable, acting in the direction favorable to the variation of the magnetic flux that produced the magnetic field of the electron picker thus having created a north pole and a south pole, confronting the north pole with the south pole thus attracting the earth's electron flows towards the coils, thus accelerating the fluxes and increasing the intensity of the current induced by the electron pickers, generating an electromagnetic field and increasing its force with greater intensity of the current moving in the connecting link between the coils, inducing the current from the north pole to the south pole circulating the magnetic energy with current without voltage, contrary to the law of homs (current is inverse proportional to the voltage, the higher the voltage the higher the current and the lower the current the higher the voltage).

PURPOSE AND BRIEF DESCRIPTION OF THE INVENTION

The object of the present invention is to provide a "MAGNETIC FIELD ELECTRONIC CAPTOR" which produces low power magnetic / electromagnetic field supplied from the initial source for coil power (1 and 2) resulting in the field forming current. magnetic / electromagnetic resistor at the coil interconnecting conductor link (s) (8 and 9) which originates from the instantaneous uptake of electrons from the earth, this 5 provides the current flow of electrons across the grounding loop that induces the core (s) of the coil (s) (1) and (2) through the conducting member (s) (10) that interconnect (s) the coils (1 and 2) to the grounding loop that is in contact with the earth acting in a favorable direction to the variation of the magnetic flux that starts to generate magnetic field, 10 thus creating a north pole and a south pole, becoming the supply endless current without resistance in the link (s) (s) (8) and 9) of interconnection of coils (1 and 2), where the electron current starts to move with voltage or without electrical voltage, a fact that is subject to the form of connection of the electrical circuit.

Electron pickup enables field formation

through the instantaneous capture of electrical current at any electrical voltage depending on how the electrical circuit is wired and how the effect of current flow on the conductor link (s) (8 and 9) is intended to be used. of interconnection of the coil (s) (1) and 2) which is coming from any matter through the electromagnetic force.

The configuration of the diagram that forms the type of structure of the open and closed electrical circuit, allows the capture through electromagnetism, according to p. (1) fig. (1), p. (5) fig. (1) and p. (6) fig. (1) where electrons are captured through the grounding loop at the center of the core of the coil (s) (1 and 2), ie an open circuit supplying electron current from the grounding loop to the core of the ( (s) coil (s) (1 and 2), thus creating a new concept for the capture and current formation of unstressed (unpolarized) or unstressed (polarized) electrons in the conductor link (s) (8 and 9) for interconnecting the coils (1 and 2).

With the new principle of closing the open and closed electrical circuit arises the physical effect of electron capture coming from any matter through the electromagnetic force of attraction and repulsion.

Using other combinations of electromagnetic or electromagnetic electro-mechanical equipment or by combining superconducting magnets, or any other type of material using the same principle of closing the open and closed electrical circuit with the potential difference, it is also possible to reach the same physical effect of electron capture through the force of attraction and electromagnetic repulsion.

The advantage of the electron picker over the other forms of electromagnetic / magnetic field generation is that its generation by instantaneous electron capture does not harm the environment, because it is used as a power source to capture electricity from the coils (1 and 2) for the operation of the electron pickers, which in turn has a very small consumption in relation to the captured current. The low power consumption ratio is 1 x 1000, 20 with consumption 1 and capture generation 1000 times higher, and this equivalence between consumption and capture generation may be higher or lower than this ratio.

It is possible to control the temperature at the interconnecting link (s) (8 and 9) of the coil (s) (1 and 2), which is at room temperature or if it is preferred it may be hot Depending on the construction and suitability of the thermal insulation of the coil (s) (1 and 2), which may be suitable for higher temperature magnetic fields, the temperature and current are increased by creating resistance through turns made with the conductive link (s) (8 and 9), adding more turns with the interconnecting conductor link (s) (8 and 9) around one of the coil (s) (1 and 2), the temperature will rise by increasing the number of turns as needed and the purpose of the sensor.

Another advantage of the electron picker of the invention is that the pickup can carry electrons from one point, "A" to one point "B", without voltage drop on the conductor link (s) (8 and 9). ) for interconnecting the coil (s) (1 and 2), regardless of the circuit distance, this technology can be used for various purposes.

Another advantage of the present invention of the electron picker is in its constructive form as it is a simple and compact equipment with low energy consumption and low manufacturing cost, and which generates magnetic / electromagnetic field to be used by all types of machines and equipment. which uses the magnetic / electromagnetic field effect.

Another advantage is that it produces voltage-free magnetic field using as its initial pickup force, electric energy.

Additionally, another advantage of the present invention of the electron picker is that it can produce low, medium or high voltage magnetic / electromagnetic field.

BRIEF DESCRIPTION OF DRAWINGS

The present invention "ELECTRONIC CAPTOR FOR MAGNETIC FIELD" will be described in more detail below based on figures: Fig. (1) p. (1) Single phase core is an illustrative figure of electromagnetic phenomenon in the turns around the cores of the captor coils.

Fig. (1) p. (2) exploded view of the iron yokes of the

coil.

Fig. (2) p. (2) exploded view of primary coil.

Fig. (3) p. (2) exploded view of the secondary link coil.

Fig. (1) and (2) p. (3) exploded view of the two coils of

facing each other, column type model.

Fig. (1) and (2) p. (4) exploded view of two coils facing each other, rounded model.

Fig. (1) p. (5) Electrical diagram of two coils with polarized link.

Fig. (1) p. (6) Electrical diagram of two link coils

without being polarized.

Fig. (1) p. (7) Aerial view of single phase captor.

Fig. (2) p. (7) Aerial view of biphasic captor.

Fig. (3) p. (7) Aerial view of the three phase pickup.

Fig. (4) p. (7) front view of the column iron.

Fig. (5) p. (7) front view of square type iron

window. Fig. (6) p. (7) front view of round type iron. Fig. (1) p. (8) illustration of Faraday's Law. DETAILED DESCRIPTION OF THE FIGURES AND INVENTION "ELECTRONIC CAPTOR FOR MAGNETIC FIELD."

On p. (1), fig. (1) and p. (2), fig. (3), show in simplified form the single-phase coil of the invention formed by the single-phase column type core, with winding and loop insulation system around the core.

The core is formed by the upper and lower yoke (1), the central column (3) and two lateral columns (2) and (4) concentrically mounted to the core is the internal winding (6.2), usually called low voltage, which can be and the winding of the right (8) and left (9) ends of the interconnecting conductor link (8 and 9) of the coils (1 and 2).

The loop insulation system (7) around the core is formed of solid electrical insulating material that covers the core window space that is occupied by the coils. We call the core window the space formed by the central core leg (3) and the lateral core legs (2) and at the height of the core legs (3) and (2) on each core leg (3) and (2). a set of loops is mounted forming this set by the outer coils (8) and (9).

The wiring of the electrical circuit of the sensor must be as follows: the outer loops of the connecting link (8) and (9) on p. (3) fig.s (1) and (2) must be interconnected by terminals, solder, connectors or any other type of connection, point (9) of fig. (1) with point 9 of FIG. 2 and point 8 of FIG. (1) with the point (8) of fig. (2) thus closing the conductive link connecting the coils, with the coils of fig. (1) at points (5) and (6), and also supplied with voltage to fig. 2 of points 5 and 6, another form of connection is to connect point 5 of FIG. (1) with point 5 of FIG. 2 and the 5 point 6 of FIG. (1) with point 6 of FIG. (2) In this way the coils of FIG. (1) and fig. (2). The interconnecting conductor link of the coil (s) may be used as a power supply (9). The diagram shows the electrical circuit polarizing or not polarizing the coil interconnecting conductor according to 10 pg. (5) fig. (1) and p. (6) fig. (1), the polarized connection, a conductor is inserted from point (5) to point (9) or from point (6) to point (8). The non-polarized connection as shown in fig. (1) p. (6) is the untensioned current that travels without resistance within the conductive link of the coils.

The capture and formation of the field

magnetic / electromagnetic occurs at the interconnecting conductor link (s) (8 and 9) of the coil (s) (1 and 2) induced by the interconnecting conductor member (10) to the ground loop, generating thus the capture of electron flux.

By the principles of physics and theories of Lenz and Faraday

We know that when connecting a coil winding the AC power supply generates a magnetic flux (11) circulating in the coil core (3), (2) and (4), induced by the grounding loop at the same frequency. of electrical voltage in the turns around the core.

For formation of turns (6.2), the presence of an electrical conductive material around the core is necessary to obtain the circulation of the electric current through the conductor around the core (12) and (13) of the coils.

Page (1) and (2) Reference (1) Coil Core Yoke.

Page (1) Reference (2) Left Side Column of the Coil.

Page (1) Reference (3) Center Column of Coil Core.

Page (1) Reference (4) Right side column of the core.

Pages (2), (3), (4), (5), (6), Reference (5) Coil Power Lead, Phase or Neutral.

Pages (2), (3), (4), (5), (6), Reference (6) Coil Power Lead, Phase or Neutral.

Page (2) Reference (6.2) Primary Concentric Coil Winding.

Page (2) reference (7) center column isolation.

Pags (2) and (3) fig. (1) reference (8) conductive member interconnecting link of coils.

Page (2) and (3) fig. (2) reference (9) conductive member interconnecting link of coils.

Page (1), (3), (4), (5) and (6) reference (10) conductive member interconnecting with the grounding loop.

Page (1) reference (11) - electromagnetic flux in the core

of the coil. Reference (1) (12) and (13) - Circulation of the electric current through the conductor around the core of the coils.

Page (5) fig. (1) reference (9) - electrical diagram of the phase or neutral polarized sensor.

Page (6) fig. (1) Electrical diagram of unpolarized sensor.

Page (7) Reference (1) Single Phase System.

Page (7) reference (2) biphasic mode system.

Page (7) part number (3) three-phase system.

Page (7) part number (4) type coil iron shape

column.

Page (7) part number (5) square window coil iron shape.

Page (7) part number (6) coil iron shape

rounded.

Page (8) reference (1) Illustration of Faraday's Law.

The coil (s) may be with the voltage from 0.1 OV to 500KV and may be their voltage (s) higher than or lower than these voltage (s).

Although the present invention has been described with reference to the preferred embodiment and practical applications thereof it is apparent to those skilled in the art that a variety of modifications and changes may be made without departing from the scope of the present invention which is intended to be defined by the claims. attached.

It will be understood that each of the elements described above, or two or more together may also find a useful application in other types of methods and effects which differ from the type described above.

Claims (32)

1. “MAGNETIC FIELD ELECTRONIC CATCH” refers to an electromagnetic device, a pickup comprising coil (s) (1) interconnected with other coil (s) (2) or through the combination of coil (s) ), electromagnet (s), inductor (s), or magnet (s) which must be interconnected by one or more interconnecting conductor link (s) (8) and (9), which In turn, the grounding loop must be interconnected by the grounding conductor member (10), which is CHARACTERIZED because it produces a magnetic field with low power consumption supplied from the initial source for the supply of coils (1 and 2). The current generated and moving in the interconnecting conductor link (s) (8 and 9) of the coil (s) (1 and 2) for formation of the magnetic field originates from the instantaneous capture of electrons through the grounding loop with the technical objective of producing magnetic / electromagnetic field through the capture of electrons, which can be used for levitation and / or propulsion of any kind of mass that occupies a place in space, among them we highlight, in general, machines, equipment and objects, being fixed or movable that can be of any size and weight, either through levitation electromagnetic, or magnetic levitation and repulsion, or magnetic attraction levitation, or magnetic induction levitation, or electromagnetic rotation levitation and propulsion, or for voltage-free magnetic field formation for therapeutic use, medical treatment. 2. “ELECTRONIC CAPTOR FOR C / ttof> 0 MAGNETIC” according to claim 1 CHARACTERIZED by feeding the coils (1) and the coil (s) (2) may be fed (s) with a voltage of 0,10 V to 500 KV, which voltage may be higher or lower than these voltage (s). 3. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED by capturing alternating or direct current AC / DC of 0.10 A at thousands of hundreds of KA or more than 1000 MA and its amperage may be higher. or less than this amperage. 4. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED because it is a new form of low power consumption electromagnetic / magnetic field generation, producing electric current through the effect of capturing electron fluxes, producing the orderly movement of the electrons which is the electric current in the coil interconnecting conductor (s) (8 and 9) (1 and 2). . 5. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized in that the interconnecting conductor (s) (8 and 9) of the coil (s) (1 and 2) may be biased with voltage equal to or equal to the voltage of coil (s) (1 and 2) at any voltage from 0.10 V to thousands of hundreds of KV or less than this voltage (s). 6. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to Claim 1, characterized in that it picks up electrons for electromagnetic / magnetic field formation at any single phase, two phase or three phase power from 1VA to 1000 MVA, and their power may be greater than or less than these. powers. 7. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED because it is possible to appear the magnetic, electromagnetic field with other types of devices that induce current through the magnetic field that appears in the conductor link (s). (s) (8) through the conductive member (10) interconnecting with the grounding loop or replacing the grounding with the closing of the coil cores. 8. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized in that the coil (1) or the coil (2) can be replaced by superconducting electromagnets or superconducting inductors or magnets, regardless of the amount to be used; depending on the size of the pickup circuit of the interconnecting conductor link (s) (8 and 9) of the coil (s) (1 and 2). 9. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to Claim 1, characterized in that the coil (s) (1 and 2) may have at least one or more than one conductive link (s) (8). and 9) interconnecting, having up to tens, hundreds or hundreds of thousands of conductive link (s) (8 and 9) surrounding and interconnecting coil (s) (1 and 2). 10. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED because the length of the interconnecting conductor link (s) (8 and 9) of the coil (1 and 2) can be be 100 cm to 100,000 km, according to the purpose and need of the circuit, the distance may be less than or greater than this measurement, and its constructive, anatomical or geometric shape may have any shape during the course of the circuit (s). ) of the link (s) (8 and 9). 11. "MAGNETIC FIELD ELECTRON COLLECTOR" according to claim 1 CHARACTERIZED for producing magnetic, electromagnetic field through electromagnetic force generating electron movement without electrical voltage at the conductor link (s) (8 and 9 ) for interconnecting the coil (s) (1 and 2). 12. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 Characterized by the configuration of the diagram which forms the type of structure of the open and closed electrical circuit, which enables the capture by electromagnetism, as shown on page (1) figure ( 1), page (5) figure (1), and page (6) figure (1), where electrons are captured through the grounding loop at the center of the core of the coil (s) (1 and 2), or ie an open circuit supplying electrical current from the grounding loop to the core (s) of the coil (s) (1 and 2), thus creating a new concept of voltage pickup and polarization or polarization with tension the coil conductor link (s) (8 and 9) of the coil (s) (1 and 2). 13. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized by the occurrence of the physical effect of electron uptake from any matter and the formation of electric current through the electromagnetic force of attraction and repulsion. 14. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED by the new principle of closing the open and closed electric circuit with the potential difference, allowing the occurrence of the physical effect of electron capture from any matter through electromagnetic force of attraction and repulsion. 15. "MAGNETIC FIELD ELECTRON COLLECTOR" according to claim 1, characterized in that it produces a voltage-free magnetic field using as the initial power of capture electric energy. A "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized in that the coil (s) (1) and (2) may also be at least one core superconducting coils, and may have more cores, and can be of any anatomical, geometric or silicon iron or any other suitable metal shape with columns or without columns and the core (s) being formed of at least one or several number ( (s) of breech-connected limbs (legs) which together form one or more core windows. 17. “MAGNETIC FIELD ELECTRONIC CAPTOR” according to claim 1 CHARACTERIZED because grounding may be replaced by insulated core or any other type of conductive element that performs the function of grounding or any other source that releases and remains. negatively charged that can supply electrons through the force of attraction and electromagnetic repulsion. 18. “MAGNETIC FIELD ELECTRONIC CAPTOR” according to claim 1 CHARACTERIZED because the neutral cannot replace the ground when the conductive member (10) is positively charged, and when the coils are negatively charged the neutral will become positive, when the coils are positively charged the neutral will become negative again. 19. "MAGNETIC FIELD ELECTRONIC CATCH" according to Claim 1, characterized in that the pickups may be single-phase, two-phase or three-phase for the purpose of capturing electrons for the formation of electric current for the development of the electromagnetic field with voltage or without electrical voltage. 20. “MAGNETIC FIELD ELECTRONIC CAPTOR” according to claim 1 CHARACTERIZED because the primary coil winding shall be made of enamelled copper conductor members or any other suitable metal, and the cross-section shall be sized according to the desired voltage and current of the coil (s) (1 and 2). "MAGNETIC FIELD ELECTRONIC CAPTOR" according to Claim 1, characterized in that it is possible to control the temperature in the interconnecting conductor (s) (8) and (9) of the coil (s). (1 and 2), which is room temperature or if preferred may be hot, depending on the construction and suitability of the thermal insulation of the coil (s) (1 and 2), which may be suitable for temperatures At higher temperatures, the temperature and current captured are increased, creating resistance through turns made with the conductive link (s) (8 and 9), adding more turns with the link (s). conductor (s) (8 and 9) around one of the coil (s) (1 and 2), the temperature will rise as the number of turns increases as the sensor needs and aims. 22. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED because at least one interconnecting conductor link (8 and 9) with at least one coiled loop is inserted around the coil core (1 and 2). first coil (1) and at least two turns winding the coil (2) and the other coils, which can be more or less turns on each of the coils (1 and 2), this winding and number of turns are directly related to the amount current to be captured and the temperature rise along with the electromagnetic field. 23. “MAGNETIC FIELD ELECTRONIC CAPTOR” according to Claim 1, characterized in that the connection of the sensor to the grounding wire is made with a bare or insulated conductor member (10) or any other suitable metal which may have any anatomical or geometrical shape by turning around in a “knot” shape and placing it close to the interconnecting conductor link (s) (8 and 9) of the coil (s) (1 and 2), preferably near the coil (1 or 2), this connection of the captor to the grounding loop can also be made, without the use of the knot, by approximation or through connectors, terminals, welding, busbars or any other type of connection. connection. 24. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to Claim 1, characterized in that the conductive member (10) which interconnects the sensor the grounding loop may or may not be connected to the load output. A "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized in that it produces magnetic / electromagnetic field by electron uptake to be used for levitation and / or propulsion of any mass that occupies a place in space; among them we highlight, in general, machines, equipment and objects, which can be of any size and weight, either through electromagnetic levitation, or magnetic levitation and repulsion, or magnetic attraction levitation, or magnetic induction levitation, or from levitation and electromagnetic propulsion by rotation or for magnetic field formation with voltage without current for therapeutic use, medicinal treatment. 26. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED because the power consumption of the coil (s) (1 and / or 2) is very small relative to the current from the link ( (s) interconnection conductor (s) (8 and 9), where the ratio of low electricity consumption is 1x 1000, with consumption 1 and generation by capture being 1000 times greater than consumption, which may be equivalent between consumption and uptake generation is higher or lower than this ratio. 27. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized in that it produces a magnetic / electromagnetic field that originates from the instantaneous capture through the electric current flow in the core (s) of the coil (s). (1 and 2) acting in a direction favorable to the variation of the magnetic flux that generates the magnetic field, thus creating a north pole and a south pole, with the endless supply of electric current without resistance at the link ( the conductor (s) (8 and 9) of interconnection of the coil (s) (1 and 2), where the electron current starts to move with voltage or without voltage, which is subject to connection form of the electrical circuit. 28. “MAGNETIC FIELD ELECTRONIC CAPTOR” according to claim 1 CHARACTERIZED because they must be protected, installed in a closed or open box or without box, and can be of any type and shape the enclosure (box) of any kind of material. always obeying the technical standards that refer to the degree of protection of the electrical equipment, according to the environment and the supply and collection voltage to be used, for use in aerial installations, above ground, underground, submerged for use. indoors or outdoors. A "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized in that the interconnecting conductor link (s) (8 and 9) may also be of superconducting wires or cables. A "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED because the primary coil winding can be made with metal conductive members using superconducting wires or cables, and the cross section must be sized according to voltage and current. of the spool (s) (1 and 2). 31. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1 CHARACTERIZED because the coils (1 and / or 2) can be fed at low, medium or high voltage and the ) interconnecting conductor link (s) (8 and 9) may be supplied with the same voltage as coils (1 and 2) or the conductor link (s) (8 and 9) interconnecting the coil (s) (1 and 2) may be powered, polarized with the voltage from another source and that voltage may be less than or greater than of the spool (s) (1 and 2). 32. "MAGNETIC FIELD ELECTRONIC CAPTOR" according to claim 1, characterized in that they may have two more coils (1 and 2), may have up to tens, hundreds or thousands of coils (1 and 2) interconnected to the circuit closure. magnetic / electromagnetic environment, where the current moves in the circle formed by the conductive link (s) (8 and 9).