BR102022006468A2 - ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION IN HIGH VOLTAGE ELECTRIC FIELDS - Google Patents

Abstract

process of electron flow through wireless interaction, in high voltage electric fields. The present invention, in the area of electrical energy generation, refers to the process of electron flow through wireless interaction, to cogenerate electrical energy, being in the vicinity of electric fields of high voltage transmission lines and others, for use under demand or for recharging in electrical energy accumulators such as batteries and the like, through the process applied to its component elements, operationally and physically, both modular and scalable.

Description

[001] The invention described here refers to the patent application for an ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, for cogeneration of electrical energy from the arrangement of three or more electrodes that aims to use electrical energy released in the vicinity of electromagnetic fields, such as high voltage transmission lines, in which the influence of the electrical component of the high voltage electromagnetic field conducted by electricity transmission lines, or any field source electromagnetic, such as inductors and transformers, acts on the arrangement of electrodes confined in a container in the presence of a gas or more gases in the same atmosphere, cogenerating electrical energy that can be stored or feed electronic circuits.

[002] This induction of the electrical component acts on different types of confined gases, mainly on noble gases contained in the periodic table and this action in conjunction with the electrodes generates a useful electrical current, which in turn, such electrodes are connected to conductive terminals of electricity, through which the electric current generated between the electrodes will flow, and the arrangement may contain one or more pairs of electrodes and the electric current between these terminals comes from the ionic transition permeability of this confined gas. This useful electrical current is capable of powering a small sensor-type electronic circuit.

[003] Various forms of non-conventional and renewable energy are being considered as possible energy sources, to meet the ever-increasing demand for electrical energy. As stated in the seventh Quarterly Electricity Consumption Bulletin, referring to the third quarter of 2021, published by EPE - Energy Research Company, electricity consumption grew 4.5% in the last quarter of 2021 (EPE - Energy Research Company. “Quarterly Electricity Consumption Bulletin”. Year II, Number 7, November 2021).

[004] Currently, several works cite electrical energy generation and cogeneration processes. This innovation is presented as a strategic cogeneration source to complement energy efficiency aid systems and could become an alternative support for mobility assistance and energy storage supply.

[005] The cogeneration of energy from the electrical component of the electromagnetic field can be considered as a dispersed electrostatic field and is a source of clean energy that does not generate any types of harmful pollutants and has practically unlimited availability, as the field generating sources electromagnetic waves occur in hydroelectric alternators, in electrical energy conductor cables, mainly in high voltage transmission lines, in substations and also in the difference in electrical potential between the sun and the atmospheric environment.

[006] However, technologies used for the practical use of alternative sources of electrical energy, such as wind and photovoltaic, are still very expensive to implement. What is proposed in the creation described is a disruptive way of improving energy use, recovering electrical losses due to dispersion in the atmosphere around high voltage lines, for example. The described technology will significantly contribute to efficient cogeneration, as a means of recharging electrical energy accumulators.

[007] The state of the art indicates some attempts at technological solutions for different processes, materials and system operating conditions, which have as their main objective the production of energy through electrical induction. Some technologies were identified in searches carried out in patent banks.

[008] Patent WO2013104042 presents an apparatus that includes a device for generating an electromagnetic field powered by a source of electricity whose coils are surrounded by a single conductive element forming a closed circuit with itself, which is connected by induction to at least one connecting conductive element, which is connected to a grounding mesh. These connections cause, as a new technical effect, the appearance of an electric current that circulates within the conductive element, forming a closed circuit to supply external loads.

[009] Patent WO2013104041 presents an electromagnetic device for capturing electrons from free space to generate electricity. Such a device comprises at least one device for generating an electromagnetic field powered by a source of electricity, with a core surrounded by a conductive element forming a polarized and energized closed circuit with itself. The field generating devices are connected to each other by opposite poles to stimulate the interaction of electromagnetic fields that are allocated between two hollow metallic semi-spheres in order to concentrate and increase the electromagnetic intensity, causing the emergence of an electric current that circulates in the element. conductor. These two technologies present solutions for generating energy using a magnetic field, however, they use different principles from those proposed in the “PROCESS OF ELECTRON DRAIN THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS”.

[010] Patent BR 202019005304-1 presents an energy generator for a drone, being developed for use in a multirotor with the ability to adapt to the standards required by safety, and its function is to provide the Drone with great functional autonomy resulting from this increased energy, which It does not use fuel, and its operation is entirely electric. The device is made up of two dynamos coupled to a motor, and when the motor is in motion the dynamo will also be in motion generating energy in the proportion of 12.24 or 36 Volts, depending on the model used, functioning like a Alternator of a vehicle. This technology aims to provide energy autonomy for Drones, but using a totally different principle from the technology proposed in the “ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS”.

[011] Patent BR1020130147559 presents an electron-capturing electromagnetic equipment that has an electromagnetic field generating device powered by an electrical energy source, whose turns are surrounded by the same conductive element in a closed circuit, which is connected by induction to an element interconnection conductor. These interconnections cause the emergence of an electric current that continues to circulate in the conductive element to generate electromagnetic fields for the most diverse uses.

[012] The difficulty of producing electrical energy is mainly due to the high investments required, energy recovery processes from technical losses, to those whose energy generating source dissipates as losses, either through transmission through the conductors or through heating of the systems that comprise them as well. require high investments.

[013] In this patent application, a non-invasive alternative is presented, that is, the process only needs to be close enough to this source to be influenced by the electrical component of the electromagnetic field. This cogeneration process, through the use of energy dissipated as technical loss in an electromagnetic field, as is the case with high voltage transmission lines, without the occurrence of load on the network, obtained from the neglected electrical loss in the atmosphere.

[014] To create the ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, an arrangement was designed so that in its assembly configuration, the flexibility of generating electrical energy was ensured, with a high level of sensitivity. to the excitation of the process, based on the electrical component of the electromagnetic field. As this creation comes from the different possibilities of configurations and arrangements, it becomes operational, physically modular and scalable, and in this way, the production of energy on demand is possible. Thus, the system can generate energy for various applications, from storage in accumulators, to directly connected to electronic mobility devices, or remote, such as controller circuits, inspection circuits and radio control data transmission, these being, for example, a solution to the problem of using technical loss of electrical energy, that is, the energy dissipated by atmospheric electromagnetic induction.

[015] The figure listed below illustrates in a non-limiting way the ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS.

[016] Figure 1 shows the arrangement diagram (50) of the process, with the circle surrounding the confinement container (160) and a graphic representation of the electrical (180) and magnetic (190) components of the electromagnetic field (170) .

[017] As it is a PROCESS OF DRAINING ELECTRONS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, interference with the high voltage line that feeds the electrical system, whether from a Hydroelectric, Thermoelectric, Wind, Photovoltaic source, even The fate of the high voltage line (voltage lowering substations) is negligible due to the fact that the energy supply for its operation comes from the use of the electrical component naturally dissipated as a loss of easement.

[018] The electron flow process, presented here, has as its principle the excitation of the set of electrodes and gas, confined by means of the inductive field that surrounds the electromagnetic fields. This process applies to various demands, such as monitoring circuits and charging electrical energy in accumulators, and this arrangement can be both modular and scalable.

[019] THE PROCESS OF ELECTRON DRAIN THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, by which electrical energy is generated, begins with the presence of the electrode arrangement and the gas confined in a container, subjected to the surroundings of electromagnetic fields, which is activated when surrounding an environment in which there is an electromagnetic field and specifically, under the action of the electrical component.

[020] As it is a process of cogeneration of energy from the electrostatic field dispersed around the electrified conductor cable, it only requires the use of the electrical component, with no considerable load on the energy carried by the transmission lines. In this way, interference with the nominal flow of electrical energy that passes through the transmission lines, or from an electromagnetic field source, becomes negligible, since the process works under the interaction of the electrical component to excite the set of electrodes and gas, this being a technological innovation due to the arrangement containing a flow electrode.

[021] The electromagnetic source, such as a rotor of a hydroelectric plant alternator, or an electrical transformer, implies the conduction of this field entirely through its components, the electrical and magnetic, which means a direct relationship between the required load work and energy transfer.

[022] In the request now required, the involvement of the magnetic component of the electromagnetic field is negligible, and there is no need for an inductor or ferromagnetic core that conducts this field composed of the components of the electromagnetic field. Therefore, it becomes possible, with the ionization of a gas, which associated with several phenomena of different natures, such as particle collision caused by the avalanche effect, also called gaseous multiplication, in which an electron with energy greater than the ionization energy of the gas collides with a gas molecule, generating an electron-ion pair. The new electron, in turn, can generate a new electron-ion pair and so on until the energy dissipates. Thus, considering a free electron at the origin, under the effect of an external electric field, when the field intensity is sufficient to ionize the gas, this electron will produce more electrons through successive collisions and consequently the electric current.

[023] As the electric field is between 3kV/m and 5kV/m, around a transmission line, the gas ionization rate becomes higher than the recombination rate due to the charge fluctuations generated in the ionization and, from then on, a potential difference arises between the bulb's electrodes, oscillating with the same frequency as the generating field (along the line, 60Hz). The dipole formed by one or more pairs of electrodes will provide electrical energy. It is worth mentioning that the ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION IN HIGH VOLTAGE ELECTRIC FIELDS will also work under other alternating current network frequencies.

[024] This invention represents a technological innovation, given that the ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION IN HIGH VOLTAGE ELECTRIC FIELDS acts in a controlled manner by the geometric model adopted of the electrode pairs, due to the physical configuration of this technology owner.

[025] The component electrodes to promote this innovation can be designed from materials resistant to the electrostatic effects of mass losses, such as gold, platinum, stainless steel, aluminum, titanium and doped silicon.

[026] The driving means of the ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS will be electromagnetic field generating sources, which may be any electrically conducting medium or inductor in which the induction loss will be induced in the process only by the electrical component of the electromagnetic field. This process produces a potential difference across its electrical contact terminals in alternating current, which can be rectified to direct current. This innovation is characterized by high sensitivity to electrostatic and electromagnetic effects capable of supplying electrical energy for electronic circuits and battery recharging.

[027] It is, therefore, an innovation for obtaining electrical energy with the aim of recovering losses caused by the induction of electromagnetic fields generated in conductors and electrical systems, mainly high voltage. From the influence, without physical contacts between the means - electromagnetic induction and the process - of this induction coming from the electrical conductors, a succession of effects occurs between one or more pairs of electrodes, using as means for this purpose one or more mixtures of gases confined between the electrodes or, in the environment in which these electrodes are inserted.

[028] For the electron flow process to occur through wireless interaction, in high voltage electric fields, at least one or more pairs of electrodes are arranged facing each other in the presence of a noble gas, preferably low-grade gases. energy, between and around the arranged electrodes, here called cells. One or more batteries may form a set for the process of ionic interaction and cogeneration of electrical energy to occur when the system is under the effect of the electrical component surrounding the electromagnetic fields.

[029] The arrangement of the electrodes in the PROCESS OF DRAINING ELECTRONS THROUGH WIRELESS INTERACTION IN HIGH VOLTAGE ELECTRIC FIELDS can be scaled according to demand, adopting the principle of geometric arrangement as the catalyst for the effect that releases the transition of electrons-ions, resulting in the cogeneration of electricity from the excitation caused by the electrical component of the electromagnetic field (200).

[030] The presented arrangement makes the Lonic Interaction process possible, comprising: at least three electrodes, being a2 (100), a1 (110) and c (120), arranged longitudinally; at least one connecting rod with the electrostatic atmosphere (122); at least two electrical connection terminals (141) and (143); at least one or more gases (130) mixed; by the arrangement, except for the electrical terminals, surrounded by a containment container (160). The electrical connection terminals (141) and (143) have an electrical potential difference V (140) and a direction of electrical current E (142) as indicated in Figure 1.

[031] The multiconfigurable electrodes a2 (100) and c (120) can be made from a conductive element, such as a plate, whose cutting direction for their manufacture may follow the direction of their crystalline formation (molecular arrangement). The dimensions (height, width and thickness) of the multiconfigurable electrodes a2 (100) and c (120) vary according to the process demand for the desired electrical current potential. These electrodes may have a thickness of nanometric measurements. However, it can be made with different measurements, in cases where its dimension makes it necessary to function as a structural element in the construction of the arrangement. Thus, they may have a substantially circular, triangular, rectangular, square, non-limiting shape. They may also have a protrusion, preferably in the same plane and preferably one, on one of the sides that will serve as a self-supporting mounting support and electrical/electronic connection terminal (143).

[032] It is emphasized that with the same dimensions as electrodes a2(100) and c (120), the multiconfigurable electrode a1(110) can be made from a conductive or semiconductor element, such as a screen or mesh, whose direction cutting method for its manufacture may follow the direction of its crystalline formation (molecular arrangement). The dimensions (height, width and thickness) of the multiconfigurable electrode a1 (110) vary according to the need for the process demand for the desired electrical current potential. The electrode may have a thickness of nanometric measurements. However, it can be manufactured with different measurements, in cases where its dimension makes it necessary to function as a structural element in the construction of the arrangement, as long as it complies with the same dimensions as the multiconfigurable electrodes a2 (100) and c (120).

[033] The multiconfigurable electrode a1 (110) may have a substantially circular, triangular, rectangular, square, non-limiting shape. In any format, it may have projections with the connection terminal (141), or different forms of connection, preferably in the same plane and on one of the sides, which will serve as a self-supporting support and for the electrical/electronic connection.

[034] The multiconfigurable electrode a2 (100) can be made from a material comprised of the group consisting of an alloy of aluminum, chromium, molybdenum, nickel, niobium, silicon or titanium, but it can also be used other metals, depending on the application, such as bronze, copper, brass, stainless steels with a low content of oxidizing components, such as chromium/molybdenum, among others, when for specific applications, including non-ferrous conductive materials.

[035] One or more inert gases, called noble gases, are present in the described arrangement with the function of promoting the ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, integrating the elements of the arrangement to aim for resulting activity, which is the generation of an electric current, being low energy gases, such as xenon. As it is an innovation where reasonable costs are considered, the gases commercially available and adopted, as they are low-cost gases, were neon gas and argon gas.

[036] The container (160) adopted in the arrangement (50) is made of glass and can be cylindrical in shape with walls whose thickness dimensions can be from 0.3 mm, non-limiting. It must be smooth on both transparent sides and may contain an internal anti-reflective or photoluminescent coating. The container is shaped accordingly to receive the electrodes a2 (100), a1 (110) and c (120), a gas cloud (130) surrounding the electrodes, the electrical connection terminals (141) and (143) and its The structure must be self-supporting, capable of fixing all the electrodes and containing the gas under vacuum. Internally to the container (160) it is possible to identify the movement of electrons (150) and ions (151) resulting from the Electron Flow Process Through Wireless Interaction, in High Voltage Electric Fields.

[037] The three electrodes a2 (100), a1 (110) and c (120), are arranged parallel to each other, with electrode c (120) being distant from electrodes a2 (100), a1 (110) and concomitantly with their areas coinciding metrics throughout the electrode configuration. The electrodes have at least one connection along one of their sides with a metallic and conductive terminal (141) and (143). The electrode terminal a2 (100) will serve as a self-supporting support for fixing it to the glass container. Electrodes a1 (110) and c (120) have terminals that will serve as a self-supporting support and, continuously, an extension that will serve for electrical connection.

[038] In gases there are neutral molecules and also ions of that gas. That is, many gas molecules lose electrons and become a set of particles whose total charge is positive. This set of particles is called an ion. The disruption of this technology occurs in the innovative way through the process described, in which it is possible to induce the displacement of these ions in order to move in the opposite direction to that of the electron, which is drained by the electrode a1(110) to the terminals.

[039] When surrounded by a high voltage electric field (210), the gas ions are attracted to the electrode c (120), this attraction occurs due to the fact that the electrode behaves like a cathode due to its terminal being conductor, exposed to the electrostatic atmosphere of the environment and with a lower induction differential due to the electric field of the arrangement. Due to its configuration in relation to the two opposing electrodes a2(100), ai (110), the gas ion, being positive, and attracted to the cathode, is then accelerated, and increases its kinetic energy. While moving to the cathode, this ion, when it encounters a neutral molecule, causes a shock and produces ionization, forming another positive ion and new electrons are released.

[040] The new ion formed is also attracted to the cathode, and the electrons released by the molecule are attracted to the anodes a2 (100), a1 (110). Electrode a2 (100) tends to increase the ionization potential of the gas and the electrons are drained by electrode a1 (110), composing the potential difference between electrodes a1 (110) and c (120), which in turn tend to continue conducting an electric current towards electrode c (120). Each new ion and these electrons, in turn, collide with new molecules that, through shock, are also ionized. The ionizations continue successively and, after a very short time, a sufficiently large number of ions are produced that move to the cathode, and electrons that move to the anode. These ions and electrons are electrical charges in motion, which constitute electrical current.

[041] The electric field near transmission lines varies from 3kV/m to 5kV/m and the ionization rate of the gas at low pressure is considered to be higher than the recombination rate. Due to charge fluctuations generated in ionization, a voltage arises between the bulb electrodes, oscillating with the same frequency as the field generated by the high voltage energy conductor line (210), that is, 50Hz or 60Hz, as well as harmonics of orders higher. The arrangement can also operate at different frequencies.

EXAMPLE

[042] The arrangement was designed with aluminum electrodes 40mm long by 10mm long, separated from each other by 50mm, inserted into a glass duct sealed at the ends and confined with a proportional mixture containing half of each of the gases. argon and neon built for the Electron Flow Process Through Wireless Interaction, in High Voltage Electric Fields, making use of a high voltage transformer similar to a Tesla coil, as a generator of a high voltage electric field of approximately 5600 volts, as a source generating the electromagnetic field, simulating a high voltage line in the configuration of the arrangement shown in figure 1.

[043] In this way, the arrangement behaves like a current source and two 1N4007 type rectifier diodes were connected to its terminals, to polarize the direction of the electric current, through two multimeters, measurements being taken, using a multimeter to voltage measurement and the second for measuring electrical current. The voltage obtained after passing through the rectifiers was 4,186 volts and 0.175 amps, totaling 2,637.18 watts/hour. Applied to recharge an ultracapacitor type accumulator of 2.85 volts per 1200 faraday.

Claims (4)

1. ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, characterized by comprising a containment container (160); a multiconfigurable electrode a1(110); a multiconfigurable electrode a2(100); a multiconfigurable electrode c (120); a connecting rod with the electrostatic atmosphere (122); connection terminals and self-supporting support (141) and (143); at least one confined gas (130) and present the following steps: • When surrounded by a high voltage electric field (210), the gas ions (130) are attracted to the electrode c (120), due to the electrode becoming behave like a cathode due to its conductive terminal being exposed to the electrostatic atmosphere of the environment and with a lower induction differential due to the electric field of the arrangement (50); • Due to its configuration in relation to the two opposing electrodes a2 (100), a1 (110), the gas ion (130), being positive, is attracted to the cathode, being then accelerated and increasing its kinetic energy; • While moving towards the cathode, when this ion encounters a neutral molecule, it causes a shock that will produce its ionization, thus forming another positive ion and new electrons are released; • The new ion formed is also attracted to the cathode, and the electrons released by the molecule are attracted to the anodes a2 (100), a1 (110); • Electrode a2 (100) tends to increase the ionization potential of the gas and the electrons are drained by electrode a1 (110), composing the potential difference between electrodes a1 (110) and c (120), which in turn tend then conducting an electric current towards electrode c (120); • Each new ion and these electrons, in turn, collide with new molecules that, through shock, are also ionized; • The ionizations continue successively and, after a very short time, a sufficiently large number of ions are produced that move to the cathode, and electrons that move to the anode; • These ions and electrons are electrical charges in motion, which constitute the electrical current generated. 2. ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, according to claim 1, characterized by the container (160) forming a chamber where the arrangement of electrodes and the confinement of gases and connections are housed self-supporting and electrical, being hot modeled in smooth transparent tubular or spherical glass and can be internally coated with fluorescent elements. 3. ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, according to claim 1, characterized by allowing the use of two noble gases in the same confined atmosphere of the multiconfigurable electrodes. 4. ELECTRON DRAIN PROCESS THROUGH WIRELESS INTERACTION, IN HIGH VOLTAGE ELECTRIC FIELDS, according to claim 1, characterized by being operationally and physically modulable, scalable and gradable.