BR102013000721A2 - ELECTROMAGNETIC EQUIPMENT EARTH ELECTRONIC CATCHER FOR ELECTRIC POWER GENERATION - Google Patents

Abstract

ELECTROMAGNETIC EQUIPMENT EARTH ELECTRON CAPTOR FOR ELECTRICITY GENERATION. The invention relates to equipment comprising at least one electromagnetic field generating device (1) - powered by an electrical energy source - whose turns are surrounded by at least one same conducting element in a closed circuit itself (4), which it is connected by induction to at least one conducting interconnecting element (5), which is connected to a grounding mesh, interconnections that cause, as a new technical effect, the appearance of an electrical current that keeps circulating in the conductive element in a circuit closed in itself, for feeding external loads.

Description

Disclosure of Patent Application for "ELECTROMAGNETIC EQUIPMENT EARTH ELECTRONIC CAPTOR FOR ELECTRIC POWER GENERATION" Technical Field The present invention relates to electromagnetic equipment for electric power generation and, alternatively, for thermal power generation. More specifically, equipment capable of producing abundant electricity and thermal energy from the smallest consumption of electricity.

Description of the State of the Art According to Lenz's Law, any induced current has a meaning 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 Faraday's Law formula, as follows. The modulus of induced electromotive force (£) in a conductive loop is equal to the rate of change of magnetic flux (??) over time: Equation 1 As an example of applying Faraday's Law, one can calculate the induced electromotive force in a rectangular loop that moves in or out at a constant velocity from a region of uniform magnetic field. The flux of the magnetic field across the loop-bound surface is given by: 0 = xLB Equation 2 and its variation in time is: Equation 3 So? = rLB Equation 4 and, if the loop has a resistance), the induced current is: Equation 5 A conductor traversed by an electric current immersed in a magnetic field suffers the action of a force given by: F ~ 1L xB Equation 6 Thus, by the effect of the induced current in the loop, the forces Fr _ F ~ and Fm appear. The first two cancel each other out and the third is canceled by an external force * ext, necessary to keep the loop at constant speed.

Since the force F? I must oppose the force FEXT the current (i) induced in the loop by the variation of the magnetic flux must have the meaning indicated in figure 3. This fact is a particular example of Lenz's Law.

Considering the experimental activities discussed with Faraday's Law, when a magnet is approached from a coil, the coil-induced current has a sense as shown in Figure 1. Thus, it generates a magnetic field whose north pole confronts the north pole of the coil. magnet. The two poles repel each other, that is, the field generated by the induced current opposes the approximation movement of the magnet.

When the magnet is moved away from the coil, the induced current in the coil has the opposite direction to that shown in figure 1, thus generating 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 induced current is opposed to the move away from the magnet. This behavior, present in current power generators and known as motor brake, is highly undesirable because it increases resistance and, consequently, increases energy loss.

When two electromagnetic coils are placed face to face, as shown in figure 2, there is no current in either of them. The moment a power switch of one of the coils is closed, a current arises in the corresponding coil, generating an induced current in the second coil. When the switch is closed, the corresponding coil current goes from zero to a certain maximum value which thereafter remains constant.

Thus, when the current is changing, the magnetic field generated by it, whose north pole confronts the second coil is also changing, and so is the magnetic flux of this field through the second coil. Then, an induced current arises in the second coil, whose direction is such that the magnetic field it generates tends to decrease the mentioned flux, that is, it presents the north pole confronting the north pole of the first coil field.

When the power switch is opened, the current in the first coil goes from its given maximum value to zero, the corresponding field decreases. The flux of this magnetic field in the second coil also decreases, so that the induced current now has an opposite direction. This sense is such that the field that the induced current generates is added to that field, that is, it has a south pole confronted with the north pole of that field.

Thus, there is an embodiment of the principle of conservation of energy, expressed in Lenz's Law, in which any induced current has an effect that opposes the cause that produced it.

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

If the magnet were then released, it would accelerate toward the coil, increasing the intensity of the induced current which would thus generate an ever larger field. This field, in turn, would attract the magnet with increasing force, and so on, with an increasing increase in the kinetic energy of the magnet.

If energy were drawn from the loop magnet system at the same rate as the kinetic energy of the magnet increases, there would be an endless supply of energy. This would have a perpetual motor, which would violate the principle of conservation of energy.

Therefore, it can be concluded that the current generators present a great energy loss in the electric power generation.

Objectives of the Invention The present invention aims to contribute to the generation of sustainable electric energy by proposing an electromagnetic equipment capable of producing abundant electric energy from the smallest consumption of electric energy. The above, and other objectives, are achieved by the present invention through equipment comprising at least one electromagnetic field generating device - without a core or at least one core - powered by an electrical power source - without a core or having at least one core - having their cores or any extension thereof, preferably their loops or sets of loops, surrounded by at least one same closed-loop conductive member in itself, which is inductively coupled to at least least one interconnecting conductive element, which is connected to a grounding loop, which interconnects cause, as a new technical effect, the emergence of an electric current which keeps circulating in the closed loop conductor element itself, for power supply. external. The equipment object of the present invention works as follows: the electromagnetic field generator device being fed by an electric power source produces an electromagnetic field that induces an electric current in the conductive element in a closed loop itself, creating a single interaction. between the equipment's magnetic poles and the earth's magnetic poles, there is - through electromagnetic attraction and repulsion - an endless supply of earth electrons to the closed loop conductor itself, which is connected to a grounding loop. through the interconnecting conductor element. The attracted electrons are added to the present current circulating in the closed loop conductive element itself, from which electrical power is provided for high power charging, although the equipment object of the present invention is supplied with a small power. Thus, advantageously, the equipment object of the present invention turns out to be an earth electron picker for electric power generation.

Advantageously, the present electromagnetic electric power generation or thermal power equipment provides access to this new power source through an electromagnetic field.

Advantageously, the interconnections of the electron sensor components object of the present invention cause, as a new technical effect, the emergence of an electric current that keeps circulating with or without voltage in the closed loop conductor itself, even without there is a consumer charge attached to it while the captor is on.

Advantageously, the proposed sensor may still be used for the generation of thermal energy, depending on how the effect of the flow of electric current produced in the present electromagnetic equipment is to be used.

For the generation of thermal energy in values proportional to the power of the sensor, by moving the electrons in the closed loop conductive element itself, the resistance must be increased by increasing the amount of turns that the closed loop conductive element itself gives. around the cores or any extension thereof, preferably the loops or loop assemblies of the electromagnetic field generating device, and thermal protection insulation of the electrical circuit components according to the temperature to be reached is provided. The thermal energy generated by the sensor can be used in any application, from domestic to industrial.

This technology can also be used for various technical purposes in electric machines. By “electric machines” is meant static electric machines, transformers, reactors, rotating electric machines, synchronous machines, double-feed machines, synchronous cascade current rectifiers, external pole machines, synchronous flow machines, current machines alternating or direct current machines, electro-electronic equipment and electrical resistors. Electron pickups can be single-phase, two-phase or three-phase, low, medium or high voltage. Induction capture does not impact the environment. The fact that it uses only electrical energy as a pickup force results in a negligible consumption in relation to the current generated and captured by the sensor. The ratio between power consumption and power generation in the sensor is at least 1 per 100, that is, for every 1Watt consumption of the sensor, at least 100 Watts is obtained for external load supply. The relationship, however, is not limited as it depends on the constructive form of the captor and its objectives, and the generation may be greater than 100 times the consumption.

Another advantage of the ground electron picker proposed in the present invention is that the captor can carry electrons from point “A” to point “B” without voltage drop in the closed loop conductor itself - if it is voltage-polarized - regardless of the distance between the points, depending on the power and quantity of electromagnetic field generating devices in the same phase. It is also possible to carry electrons when the closed loop conductive element itself is not polarized. In this way, the electric current is carried without voltage only through the magnetic field formed between the electromagnetic field generator device (s).

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will hereinafter be described with the aid of drawings, but are not absolutely limiting, where further details and advantages of the present invention can be observed.

The figures show: Figure 1 - A representation of Faraday's Law.

Figure 2 - A representation of Faraday's Law.

Figure 3 - A representation of Faraday's Law.

Figure 4 - A perspective view of a single phase electron picker with a coil.

Figure 5 - A perspective view of a single-phase two-coil electron picker.

Figure 6 - A representation of the effect of electromagnetic flux on the coils around the electron picker coil cores.

Figure 7 is a representation of a two-coil electrical circuit with the polarized conductive link / loop.

Figure 8 is a representation of a two-coil electrical circuit with the unpolarized conductive loop / loop.

DETAILED DESCRIPTION OF THE DRAWINGS Figure 4 shows one of several embodiments of the electron picker proposed by the present invention, wherein the pickup is single-phase and consists of at least one electromagnetic field generating device with at least one loop assembly (s) in the present case a column type electromagnetic coil (1), but coils of any kind and shape may also be used. However, the electron picker proposed by the present invention may be constructed with another type of electromagnetic field generating device, such as at least one electromagnetic inductor or electromagnet of any kind and shape, with any combination of them, and in unlimited quantities in each. electron captor phase.

Surrounding the coils turns (1), there is at least one same closed loop conductive element in itself (4), forming at least one conductive link (s) (4) - may have other shapes - making at least one turn around the coil turns (1), preferably two turns if the target is power generation, and preferably four turns if the target is thermal power generation. Both this winding and the number of turns around the coil turns (1) are directly related to the amount of current to be generated in the conductor link (s) (4).

At least one interconnecting conductor, in this case a conducting member (5) - which may be copper or any other suitable conductor, with or without insulation - interconnects the link (s) / loop (s) ) conductor (s) (4) to the grounding loop. The connection between the conductor member (5) and the conductor link (s) / loop (4) is made by electromagnetic induction. The conductive link (s) / loop (4) is also the power supply for the loads to be fed by the electron picker.

Figure 4 also shows the supply conductors (3.1) and (3.2) - phase or neutral - which are the external supply input of the coil (1). Coil power (1) may be supplied from any power source with electromagnetic potential, such as from a power grid. The electron picker can be constructed with direct current configuration or with alternating current configuration. Thus, if the power source is AC power, the captor provides AC power. If the power source is DC direct current, the captor provides DC direct current. The earth electron picker can be single phase, two phase or three phase, low, medium or high voltage. Figure 5 shows a single phase pickup with more than one coil (1) and (2), in this case with two column type coils (1) and (2), but also coils (1) and (2) can be used. ) of any genre and format. However, the electron picker proposed by the present invention may be constructed with another type of electromagnetic field generator device, such as at least one electromagnetic inductor or electromagnet of any kind and shape, in any combination, and in unlimited quantities in each phase of the electron captor.

Surrounding the coils turns (1), (2) there is at least one conductive element in the same closed loop (4), forming at least one conductive link (s) (4) - they may have other shapes - making at least one turn around the coil turns (1) and (2). Both this winding and the number of turns around the coil turns (1) are directly related to the amount of current to be generated in the conductor link (s) (4). The winding also interconnects between the coils (1), (2), forming the conductive link / loop (4), between the cores of the two coils (1), (2).

In the interconnection of the equipment with the grounding loop there must be at least one interconnecting conductive element, in this case a conductive member (5) - which may be copper or any other appropriate conductor, with or without insulation - interconnects the conductive link (s) / loop (s) (4) to the ground loop. The connection between the conductor member (5) and the conductor link (s) / loop (4) is made by electromagnetic induction. The conductive link (s) / loop (4) is also the power supply for the loads to be fed by the electron picker. It is also observed, in figure 4, the supply conductors (3.1) and (3.2) - phase or neutral - which are the external supply input of the coils (1), (2) - In the pickups with numerous coils (1), (2) The ends of the power leads (3.1) can be connected to each other. The ends of the power leads (3.2) can also be connected to each other. Thus all coils (1), (2) can be supplied with the same electrical voltage. Power to coils (1) and (2) may be supplied from any power source with electromagnetic potential, such as from a power grid.

In these pickups with numerous coils (1), (2), one and the same conductor (s) / loop (s) (4) circulate the core of all coils (1), (2).

In Figure 6, a diagram shows the induction (6) around the core “X” of the coil (1). With induction, the electric current (7) circulates in the conductive loop / loop (4), drawing the electrons from the earth, through the conductive member (5), to the magnetic field of the captor, where the electrons join the current. generated by induction in the conductive loop / loop (4) circulating between the north and south magnetic poles. Figure 7 shows how the electrical circuits of the electron picker proposed in the present invention should be made. In the diagram is shown an electrical circuit of an electron picker with the voltage polarized conductive link / loop (4). This is one of the two-coil electron picker construction (1), (2), where a conductive loop / loop (4) is polarized with voltage, ie there is a conductor connecting this conductive loop / loop ( 4) to one of the supply leads (3.1) or (3.2), whatever the phase.

Thus, electron pickups from the earth adopting this electrical circuit, that is, with the conductor loop / loop (4) polarized with coil voltage (1), (2), besides being used as external power supply, They can also be used for thermal energy generation. Figure 8 shows how the connections should be made in another electrical circuit of the electron picker proposed in the present invention. In the circuit is shown an electrical circuit of an electron sensor with the conductor link / loop (4) not polarized with voltage. This is one form of construction of the electron picker, where a conductive loop / loop (4) of the coils (1), (2) is not polarized, ie there is no conductor connecting this conductive loop / loop (4 ) to one of the supply leads (3.1) or (3.2).

Thus, electron pickups from the earth adopting this electrical circuit, that is, with the non-polarized connection, the current travels without tension on the conductive link / loop (4) that interconnects the coils (1), (2) through electromagnetic induction. They can also be used for thermal energy generation. The electrical circuit structure - open or closed on coil (s) (1), (2), and always closed on conductor link (s) (4) - turns induction current generation and electron capture by electromagnetism at the conductor link (s) (4) - where the current is generated and keeps moving with or without voltage while the coils (1), (2) are being supplied, ie while their circuit is closed. Thus, the present invention creates a new concept of electric power generation, as an electric current flowing without consumption (7) in the conductive link (s) (4) is obtained even without a consumer charge attached to it.

In addition, because the electric current (7) is induced by induction, regardless of voltage, on the conductor link (s) (4) of the captor proposed by the present invention, it can be used as a current stabilizer in single, two phase or three phase, low, medium or high voltage mains 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 types , formats, models, genres, modifications and changes that may be made or used without departing from the scope of the present invention which is intended to be defined by the appended claims.

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

Claims (11)

1. Electromagnetic earth electron-collecting equipment for the generation of electric energy, characterized in that it comprises at least one electromagnetic field generating device (1), powered by an electric power source, its cores or any extension thereof preferably being their coils. or sets of loops, surrounded by at least one same closed loop conductive element in itself (4), which is inductively coupled to at least one interconnecting conductive element (5), which is connected to a grounding loop, interconnections. which cause the emergence of an electric current that keeps circulating, with or without voltage, in the closed loop conductive element itself (4), which is the point of the external load connections, regardless of whether or not there is a load of consumption linked to it. Electromagnetic equipment according to claim 1, characterized in that the electromagnetic field generator device (1) has at least one core. Electromagnetic equipment according to claim 1, characterized in that the electromagnetic field generator device (1) is devoid of core. Electromagnetic equipment according to claim 1, characterized in that the closed loop conductor element itself (4) is biased with a voltage. Electromagnetic equipment according to claim 1, characterized in that the closed loop conductive element itself (4) is devoid of voltage bias to generate thermal energy. Electromagnetic equipment according to claims 1, 2, 3, 4 and 5, characterized in that the electromagnetic field generator device (1) is provided with efficient thermal insulation to generate thermal energy. Electromagnetic equipment according to claims 1, 4, 5 and 6, characterized in that the closed loop conductive element itself (4) surrounds the cores or any extension thereof, preferably with a greater number of turns. the loops or loop assemblies of all electromagnetic field generating devices (1), to provide greater resistance to electric current flow, to generate thermal energy. Electromagnetic equipment according to claim 1, characterized in that it is configured for use with direct current - DC. Electromagnetic equipment according to claim 1, characterized in that it is configured for use with AC power. Electromagnetic equipment according to claim 1 or 9, characterized in that it is configured for use in low, medium and high voltage electrical networks. Electromagnetic equipment according to any one of claims 1, 6 or 10, characterized in that it is configured for use in single-phase, two-phase or three-phase electrical networks of any power.