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MX2013007738A - Molecular disruptor by resonance. - Google Patents

Molecular disruptor by resonance.

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Publication number
MX2013007738A
MX2013007738A MX2013007738A MX2013007738A MX2013007738A MX 2013007738 A MX2013007738 A MX 2013007738A MX 2013007738 A MX2013007738 A MX 2013007738A MX 2013007738 A MX2013007738 A MX 2013007738A MX 2013007738 A MX2013007738 A MX 2013007738A
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MX
Mexico
Prior art keywords
dissociator
antenna
plates
fluid
washer
Prior art date
Application number
MX2013007738A
Other languages
Spanish (es)
Other versions
MX347786B (en
Inventor
David Homero Carrillo Rubio
Original Assignee
David Homero Carrillo Rubio
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by David Homero Carrillo Rubio filed Critical David Homero Carrillo Rubio
Priority to MX2013007738A priority Critical patent/MX347786B/en
Publication of MX2013007738A publication Critical patent/MX2013007738A/en
Priority to US14/902,121 priority patent/US9682358B2/en
Priority to PCT/MX2014/000100 priority patent/WO2015002524A1/en
Publication of MX347786B publication Critical patent/MX347786B/en

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Abstract

The present invention refers to a device formed by antenna units and connected to a signal generator able to disrupt or decompose molecules in solution, suspension or fluids in general, into the constituent elements thereof, in order to recycle such compounds and remove pollutant materials, which would be dangerous or harmful to human, vegetal or animal health if these are not disrupted.

Description

MOLECULAR DISSOCIATOR BY RESONANCE Field of the Invention The present invention relates to the field of elimination of impurities of a compound and more specifically to a dissociator of molecules in several stages that uses spectral patterns of very low (VF), low (LF) and average (MF) frequencies in different types of . signals, such as unitary pulses, sawtooth, square, sinusoidal, resulting from the combination of two or more of these functions, in phase or defested among themselves, inducing an antenna that produces an electromagnetic field producing an induced resonance to the element dissociate, from the fluid that passes through the antennas.
Background Gas dissociators are known that produce plasma and that use antennas and coils to dissociate a gas that passes through a chamber and that is excited by an antenna and / or a set of coils with high frequencies (VHF, UHF); however, such devices, although related to the present invention, do not constitute more than related state of the art.
Devices for treating water are also known. Among these devices are those described in, for example, patents US 7,910,006, 7,419,603, 5,326,446, etc., which: take advantage of the electromagnetic properties to treat impurities contained in the water that are generally ionized in the: water- and therefore they are affected by an electromagnetic field with proper properties. Again, this literature is provided as a state of the art relating to the present invention.
In the document with Publication No. WO 2010059751 a method and apparatus for producing hydrogen and oxygen from water is described. The apparatus comprises a dissociation chamber, a separation apparatus for separating hydrogen ions from oxygen ions and a device for ionization. In the dissociation chamber, the water can be dissociated with the help of magnetic and / or electromagnetic fields.
In the document with Publication No. WO 2005005009, equivalent to Canadian patent No. 2572434, entitled "Molecular hydrogen molecular water dissociation", it is described on page 8, referring to figure 1, that the device comprises a reactor of radiant energy transfer, which includes a first portion adapted to receive water molecules, a second portion wherein the components of the dissociated molecular water can be separated and removed and a coil, which produces an electromagnetic field when energy is applied.
Mexican patent No. 244030 relates to a water treatment system in which an electric field is used to use a cavitation chamber or shocks.
Mexican patent No. 241669, refers to a biochemical waste neutralization apparatus, which is integrated by units: neutralization chamber, refrigeration, radio frequency generator, a power generator, gas regulator, etc.
BRIEF DESCRIPTION OF THE INVENTION The present invention relates to a device capable of dissociating or decomposing molecules in solution, suspension, fluids or gas in general, in their constituent elements, in order to recycle such compounds and eliminate polluting materials that, if continued chemically bound, would be dangerous or harmful to human, vegetable or animal health.
By the present invention, molecules of, for example, acids, alkalis and carcinogenic substances that can adversely affect the environment where they are discarded can be decomposed in their constituent elements.
When a resonance frequency is applied by means of an oscilloscope that allows breaking the bonds that support it, all the molecules of compounds can be dissociated in the natural elements of which they are composed, being such asymmetric or symmetrical bonds.
| The invention consists primarily of a device comprising a set of antenna units that physically connect, not necessarily electrically, and are sealed by means of neoprene, in the center of which is located a conduit through which the fluid to be decomposed circulates. . Said conduit is formed by the union of the antenna units used.
Each of these antennas is induced a series of wave functions originated by a generator of wave function spectra that once connected in the antennas of the invention creates an electromagnetic field that derives at a resonance frequency, which acts on the fluid and causes the molecular breakdown of it. The antennas generate spectral radiation patterns in several stages because different wave functions are provided in the antennas, to more effectively affect the fluid to be treated and dissociate it in its constituent elements only in one device.
Brief description of the figures Figure 1 shows the explosion of parts of the unit antenna; where (4) is the dish of the antenna; (6) is the electrical connector of the antenna; (7) is the dish of the antenna; (9) is the balanced impedance coil; (5) is the sealing insulator; (15) is the selenoid of multiple sections and (16) is a mirror that causes resonance.
Figure 2 is the explosion of parts of the dishes of the antenna; where (7) and (8) are the conductive plates and (14) is the washer.
Figure 3 shows some ways how the exemplary windings used by the dissociator can be created.
Figure 4 is a schematic view of the explosion of parts of an antenna unit in accordance with the present invention; wherein (2) is the antenna package, (6) is the antenna electrical connector, (12) represents the output of the dissociated element; (16) represents the dielectric mirrors and (17) the assembled antenna.
Figure 5 is a schematic view of a package of concentric antennas with two outputs (10) and (12) where: (2) is the antenna support, (3) is the cover containing the assembled antennas, (4) It's the dish of. the antenna; (6) are the electrical antenna connectors and (11) is the circular space of entry of substance to be dissociated.
Figure 6 is the schematic representation of the fluid distribution duct in the dissociator made of insulating material hardened by heating.
Figure 7 is a schematic view of the dissociator in accordance with the present invention; where: (1). is, the dissociating device, (6) are the electrical connectors: de! "the antennas (which are connected to the signal generator), (11) is the circular space of entry of substance to dissociate, (12) is the output of the dissociated element, (13) is the plastic lid and (18) is the signal input of the generator.
Figure 8 represents the internal operation of the dissociator and the effect it produces in each stage to dissociate the molecules of the compounds and is a vertical view of Figure 7 where the parts that make up the device are shown.
Figure 9 is an image generated by the oscilloscope showing the wave functions and frequencies used in the Signal Generator, to dissociate the elements contained in the Descriptive Examples of the invention.
Figure 10 is a graphical representation of how a molecule goes from a polarization state to a dissociation state; stages that occur since the element to be dissociated in the invention is introduced until the dissociated elements exit the outputs (10, 12).
Detailed description of the invention The invention relates to a device that operates with a series of antennas that are supplied with different continuous wave functions, which produce an electromagnetic field in each of them, with variation of frequency and time, this is basically the technical basis of the dissociation effected by the dissociator of the present invention.
Considering the figures previously described,. the dissociator (1) comprises an unlimited number of unidadesl.de antennas (figure 1) to generate a radiation of spectral patterns (see figure 8) of resonance frequency in multiple stages. The antenna unit comprises a body or support (2) in which a plurality of concentric antennas (Figure 1) are placed, whose center is an empty circular space (11) through which a conduit (Figure 6) of material is passed. suitable, so that through it flows the fluid to be treated.
The dissociated element (s) exit through the lateral outputs (10) (12) and the wave function is supplied in the connectors (6).
The dissociator of the present invention is constructed with "n" number of these antenna units (figure 1) until achieving the desired pattern depending on the amount of fluid and element or elements to be disassociated and the fluid circulating in the shortest time interval, necessary for its treatment. The antenna units (figure 1) are composed of two plates (7), separated by a washer (14) between the plates (7) and around the washer (14) a winding is created, either as illustrated in Figure 3, starting and ending in electrical connectors or eye-type terminals with plastic lining (.6) for these units, which can be connected to the same wave function generation source or to individual or group sources , depending on the fluid to be dissociated.
The concentric antenna (see Figure 4) comprises two conductive elements or plates (7,8 in Figure 2), and between them is placed a balanced impedance Z coil (9) of a conductive material? where ? represents the conductivity with a number? of windings of a caliber f in such a way that maintaining the ratio of the material that make up the plates (7, 8) with the material of the coil, the number of windings, the diameter of the wire, the wave function, an antenna is created active to dissociate the compound in its constituent elements.
The materials used in both the coils and the plates are the so-called metallic conductors in which the conduction is electronic, that is, the charge carriers are free electrons. Metals and alloys belong to this group. The electrical conductivity is a property linked to the electric current that can flow through a material when it is subjected to an electric field, likewise and depending on the case of use Coil (9) or dish (7,8) of antenna, it will be indispensable requirement that the material of the plate (7,8) also belong to the group of Magnetic materials, that is to say: that a material is magnetic, when it is observed that its atoms or ions behave as if they were small magnets that interact with each other ' . "This behavior has its origin · in the movement of the electrons inside the atoms, since every electric current produces a magnetic field". In these cases, it is said that the atoms have a magnetic moment different from zero, which is characterized by; its magnitude and the direction in which it is oriented. The dishes that are have tested are of the following materials: ferrous metals for commercial use, steel, stainless steel, iron; The following materials have been tested as materials for the coils: brass, aluminum, copper. In both cases (plate or coil), they have been coated: silver, gold, tin, lead, zinc, magnesium, as well as alloys among the aforementioned.
CONSTRUCTION EXAMPLE A "molecular magnetic resonance dissociator (DMRM)" (1) was constructed, comprising four antennas (figure 1) that were constructed in the following way each: Two plates (7,8) of stainless steel of the type X3CrNbl7 according to the European standard (EN 10088), of 22 gauge in circular form of a diameter of 15 cm, two perforations, one of 0.625 cm in their upper end with a distance of 0.625 from the edge; To the center of the greater radius was drilled a diameter of 2.5 cm, a washer (14) was welded to the circular center made with 20 gauge stainless steel sheet with a radius of 3.5 cm and a 2.5 cm perforation in the center, a the one that was welded to another plate making a reel, (see figure 7); a thread was made inside the reel in the union of the washer with the two plates in the perforation, making a thread so that it will work as a nut inside the washer of the reel and that will allow to join other reels built of equal form through the conductive duct (see figure 8).
A coil (9) was built between the plates (7,8) with wire of the Nacobre brand of type S0LD7ANELM. R. YLON 130 ° C 52 gauge. This coil was created by placing a cable terminal in the hole with a terminal (6) on top of one of the plates and rotating on the reel of a crank mounted a vise, until you reach to the top and cover the entire reel, leaving the other end of the cable in the hole of the adjoining plate; At both ends connectors were placed, which conduct the electric current. The antennas are coated on the inside and outside to create a space where the dissociated elements move and flow through the exit cavity.
The four antennas were joined with a tube (figure 8), placing between them a circular insulator based on rubber thickness of 0.007 cm, creating a space between them and a mirror (16) between the insulators. | | The tube (figure 6) was constructed in the following way: a copper mesh and a flexible iron mesh was taken and a circular cylinder 12.5 cm long by 2.5 cm wide was formed, taking as mold a circular cylinder with thread 20 cm long and 2.5 cm in diameter and the mesh was wound around the mold; later it was covered with carbon fiber tod'á "the surface of the mesh to give it rigidity and it was enroscó to the fiber carbon a wire to give the shape of the thread, and heated to a temperature of 300 ° C for 90 minutes to give it rigidity.
The antennas were attached to the tube and they were introduced in a box (2) made with a plastic cube of 15 X 30 X 2.5cm, which was drilled 15cm from the center and crossing to the other end. it made a slot in one of the edges so that the terminals of the coils (6) would be allowed to exit, and on the sides a perforation of 1.25 cm from the outside towards the edge of the washer was made without reaching the tube, that would allow to reach to perforate all the antennas (see figure 9). To this perforation a thread was made and an Nipple of PVC (11,12) with Teflon tape around the thread of the PVC Nipple of 1.25 cm that covered the perforation and was sealed all with silicon of the brand CO EX to guarantee that everything flowed in the corresponding cavities; then it was sanded until the bucket was devastated so that it was at the level of the reels at each end of the dissociator.
Once developed the. primary dissociator were manufactured 7 devices (dissociators) plus, and were introduced in a plastic container, with the necessary cavities to allow the output of the connectors, nipples and the fluid pipe. Finally, plastic caps (13) were made of the same material that contains the antennas, and were sealed and fixed: With stainless steel screws of unknown brand, to avoid corrosion. · ..! | Once the dissociator was completed, a 6-channel wave signal generator of the HIGHLANDER TECHNOLOGY brand was connected and this in turn was connected to a signal retarder of the same brand and different fluids were passed through the central tube and placed a stopper at the other end of the tube ("depending on the case of the type of fluid") and different elements and materials were obtained by the lateral and lower outlets.
EXAMPLES OF APPLICATION In the case of Tap Water: Rubber hoses of the laboratory type were placed, of unknown brand where test tubes were placed with cork stoppers, the test tubes were filled with water and introduced head in a tub of 23 X 30 cm, which was filled with water to exceed the mouth of the tubes; each tube was sealed with a rubber stopper with two holes where two glass tubes were placed and one of them was connected to one of the hoses of the dissociator: at the exits (10,12) and the other tube was left without connecting anything; "" at the moment of inducing the wave functions (figure 9) and passing the tap water, different materials were obtained in each tube: in one, Oxygen, in another, Hydrogen defined by producing twice as much gas as the other; in the last: Chlorine. The latter was characterized by its smell and a resulting mixture of solid materials, which are considered as yet unidentified salts.
As can be seen from the example, the elements to be dissociated in the dissociator are in a fluid combined with other elements, organic and inorganic. The fluid is flowed through the center of the antenna (11). The dissociators can be multiple units c depending on the number of antennas that are linked to each other.
As the number of antenna units increases (figure 1), the volume to be dissociated from the compound, or multiple elements can be increased simultaneously, by applying a single or multiple frequency spectrum, respectively.
As can be seen, each antenna is separated by an insulator or dielectric at a distance T where the dissociated element will be obtained by the wave function that is induced to the coil, which creates a resonance frequency that corresponds to each element, leaving the elements by the exit (10,12) and the discriminated elements will leave as residue on the back.
In each antenna device there may be a resonance frequency or several, as many as there are coils; for this reason there are outputs on the sides of the dissociator. for the dissociated elements and an inlet and outlet at the back of the dissociator to join a new device, or it may have a duct terminator.
All windings increase their number of turns from the center of the antenna out; in this way, the dissociation stage is given by exciting the incoming fluid until the end of its path where the connection breaks. The positions of the windings produce patterns of electromagnetic radiation in different ways.
With respect to figure 10, it is shown how the molecule goes from a state of polarization to a state of dissociation.
As far as the inventor of the present invention is aware, there is no device for dissociating molecules in their constituent elements as performed by the present invention, without the use of electrodes submerged in the medium to be dissociated.
For the case in Agua Salitrosa: This water is known for being the viscous liquid that is obtained from deep wells, in which the water is mixed with salts, minerals, stones and, in some cases, oil (crude oil); the objective is to separate the water, the stones, and leave the minerals and the oil in the same mixture, which goes into separation by industrial processes of refining. Currently, this process. It is done using floating roof tanks and adding chemical substances that make it possible to float the water and proceed in this way with the separation.
In our example, water is used with crude oil, extracted from a well of Petróleos Mexicanos.
The prototype that was used was initially the same for the case of tap water, with the modality that a rotating drum of rock separation greater than 0.01 mm thick was added to the entrance of the dissociator.
Rubber hoses of the laboratory type, of unknown brand, were placed where test tubes were placed with cork stoppers; the test tubes were filled with water and were introduced head-first into a tub of 23 X 30 cm, which was filled with water until over the mouth of the tubes. Each tube was sealed with a rubber stopper with two perforations where two glass tubes were placed: one of them connected one of the hoses from the dissociator to the outlet (10,12) to each tube with hoses and the other tube was He left without connecting anything. At the moment of inducing the wave functions and passing the salty water, in each tube different materials were obtained: in one, Oxygen, in another Hydrogen defined to produce twice as much gas as the other. The remaining material was placed in a tub where the oil was poured with the mineral salts in the form of sand.
It is important to note that the aforementioned descriptive examples are included in a non-limiting manner, since with the present invention it is possible to dissociate virtually any fluid in their elements.

Claims (13)

1. Molecular resonance dissociator characterized in that it comprises a series of antennas to which various continuous wave functions are supplied to produce an electromagnetic field in each of them, with variation of frequency and time, through which the fluid passes, to dissociate.
2. The dissociator according to claim 1, characterized in that said dissociator comprises: at least one antenna comprising at least two antenna dishes; electrical connectors of the antenna; balanced impedance coil; sealing insulation; multi-section selenoid; antenna packaging; at least two outputs of dissociated element; dielectrics; central circular space of entry of substance to be dissociated; fluid distribution duct in the dissociator; plastic cap; and generator signal input, wherein said antenna dishes comprise at least one washer.
3. The dissociator according to claim 1, characterized in that said dissociator comprises a plurality of antenna units that generate a radiation of spectral patterns of resonance frequency in multiple stages.
4. The dissociator according to claim 1, characterized in that the antenna unit comprises a body or support in which a plurality of concentric antennas are placed, whose center it is an empty circular space through which a conduit is passed so that the fluid to be treated circulates through said conduit.
5. The dissociator according to claim 1, characterized in that the antenna unit comprises lateral outputs through which the dissociated element or elements exit and the wave function is supplied in the connectors.
6. The dissociator according to claim 1, characterized in that said dissociator is constructed with "n" number of these antenna units until achieving a pattern suitable to the amount of fluid at or the elements to be dissociated and at the shortest time of circulation of the fluid.
7. The dissociator according to claim 1, characterized in that the antenna units are composed of two conductive plates, separated by a washer; between the plates and around the washer a coil is created with a winding that starts and ends in electrical connectors or terminals that connect them to the same wave function generation source or "to individual or group sources.
8. The dissociator according to claim 1, characterized in that the two joining plates have two perforations at their upper end at a distance from the edge; at the center of the greater radius they have a perforation of diameter equal to the conduit and to the circular center they have welded a washer and a perforation to the center, to which another dish was soldered to him making a reel; inside the spool at the junction of the washer with the two plates there is a thread.
9. The dissociator according to claim 1, characterized in that the concentric antenna comprises two conductive elements or plates and, between them, a balanced impedance coil of a conductive material is placed; with said coil material, the number of windings, the diameter of the wire and the wave function an active antenna is created to dissociate the compound in its constituent elements.
10. The dissociator according to the rei indication 1, characterized in that the conduit or tube through which the fluid passes has the shape of a circular cylinder constituted by a copper mesh and a flexible iron mesh with thread covered with carbon fiber over the entire surface of the mesh, also includes wire.
11. The dissociator according to claim 1, characterized in that the materials used in both the coils and the plates are the so-called metallic conductors in which the conduction is electronic and to this group belong the metals and alloys.
12. The dissociator according to claim 1, characterized in that the plate material also belongs to the group * of "the Magnetic materials, such as: ferrous metals for commercial use, steel, stainless steel, iron.
13. The dissociator according to claim 1, characterized in that the dissociator is connected to a wave signal generator of at least 6 channels and said generator is connected to a signal retarder.
MX2013007738A 2013-07-01 2013-07-01 Molecular disruptor by resonance. MX347786B (en)

Priority Applications (3)

Application Number Priority Date Filing Date Title
MX2013007738A MX347786B (en) 2013-07-01 2013-07-01 Molecular disruptor by resonance.
US14/902,121 US9682358B2 (en) 2013-07-01 2014-07-01 Resonance-based molecular dissociator
PCT/MX2014/000100 WO2015002524A1 (en) 2013-07-01 2014-07-01 Resonance-based molecular dissociator

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
MX2013007738A MX347786B (en) 2013-07-01 2013-07-01 Molecular disruptor by resonance.

Publications (2)

Publication Number Publication Date
MX2013007738A true MX2013007738A (en) 2014-02-21
MX347786B MX347786B (en) 2017-05-12

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MX2013007738A MX347786B (en) 2013-07-01 2013-07-01 Molecular disruptor by resonance.

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MX347786B (en) 2017-05-12

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