JP2005286281A - Electric field and magnetic field using a plurality of metal poles - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To cause an electric field and a magnetic field to have chemical actions although the electric field or the magnetic field does not become a field of reduction-like or oxidation-like action. <P>SOLUTION: A ferromagnetic metal plate, an antimagnetic metal plate and a paramagnetic metal plate are tightly overlapped on a magnetic pole face of a magnet. Inherent material waves radiated by three kinds of metals are resonated inside a magnetic field, so that the magnetic field has a chemical action. The combination of iron, copper and aluminum creates a reduction-like magnetic field. The combination of nickel, copper and aluminum creates an oxidation-like field. Three kinds of bipolar metal plate magnets each tightly attaching three kinds of metal plates to both N and S pole faces are combined, so that a wide space can be made into a magnetic field having a chemical action. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for changing the chemical action and state of water, steam, fluids including air, current, electromagnetic waves, and light using an electrostatic magnetic field.

  In order to change the state and chemical action of water, steam, air, current, electromagnetic waves, light, etc., it is effective to apply an electric field and a magnetic field simultaneously. The inventor is pending a related patent. If the state of the object to be treated can be reduced or oxidized only by an electric field or a magnetic field, the applicable range can be expanded.

  It has been experimentally confirmed that a combination of three kinds of metals, namely a ferromagnetic metal, a diamagnetic metal, and a paramagnetic metal, makes the field reductive or oxidative. For example, a wire formed by twisting copper, aluminum, and iron wires or a braided strip is wound once or more to form an empty coil. It has been confirmed by experiments that water and air passing through the empty coil cross section are in a reducing state. Further, the combination of copper, aluminum and nickel results in an oxidative state. It is considered that the resonance phenomenon of the material wave produced by the combination of three kinds of metals creates a field that acts reductively and a field that acts oxidatively. The phenomenon that connects the reductive or oxidative action of these three metals with the reductive or oxidative action of the electrostatic magnetic field was confirmed by experiments. The present invention is based on this experiment.

  The range of use can be expanded if the electric and magnetic fields themselves have reductive or oxidative fields. It has a reducing and oxidizing action on the magnetic field of an easy-to-use permanent magnet.

Means to solve the problem

  It was experimentally confirmed that a resonance phenomenon was caused by superimposing substance waves of three kinds of metal elements in a magnetic field, and that a magnetic field with a strong reductive or oxidative action could appear. Three types of metals are selected from ferromagnetic iron, iron alloy, nickel, cobalt, diamagnetic copper, silver, gold, bismuth, paramagnetic aluminum, platinum, and manganese. For example, an elongated band formed by braiding metal wires of iron, copper, and aluminum is wound once or more to form a coil, and this coil is placed on the magnetic pole surface. Place a sealed container of water in the coil. Water becomes reductive. Nickel or iron instead of iron. nickel. Coils using chrome alloy wires make water oxidative. It does not depend on the polarity of the magnetic field.

  When these two coils are arranged facing each other and a voltage is applied between the coils, the field between the coils becomes a reductive or oxidative field.

  An iron plate, a copper plate, and an aluminum plate with a thickness of, for example, 0.3 mm within a thickness range of 0.01 to 10 mm are stacked in close contact with each other on the N-pole or S-pole surface of the magnet to form a one-pole / three-type metal plate magnet. A sealed container containing water was placed on the aluminum plate of this 1-pole 3-type metal plate magnet, and the change in water was confirmed. The water state becomes a reducing state. Nickel plate or iron. Chrome alloy plate or iron. Chrome. Nickel alloy plates, copper plates, and aluminum plates, one-pole, three-type metal plate magnets make water oxidative. Similarly, the 1-pole 2-type metal plate magnet without the iron plate also brings the water into a reducing state. The reason is that the main constituent metal of the magnet is iron. From experiments, it was found that when a thick iron plate, for example, 0.5-1 mm, was brought into close contact with the opposite magnetic pole surface, the action of the magnetic field was enhanced and stabilized in any case. One reason is that the influence of leakage magnetic flux can be reduced.

  A two-pole / three-type metal plate magnet in which three types of metal plates are closely stacked on the N and S2 pole faces of the magnet has a stable magnetic field effect. A strong magnet increases the distance between the magnetic poles. The effect of leakage magnetic flux cannot be prevented completely by simply attaching three types of metal plates to the NS pole faces. It is necessary to wrap the entire surface. By wrapping the entire surface of the magnet, the entire magnetic field becomes a field of reductive or oxidative action. There is no difference between magnetic poles in the reductive and oxidative effects of the magnetic field. Normally, there is no problem with a 2-pole 3-type metal plate magnet.

  Experiments were conducted on the thickness of three types of metal plates. The thin foil-shaped range from 10 microns to 10 mm was tested in 1 mm increments. There is no big difference in thickness between diamagnetic metal and paramagnetic metal. Ferromagnetic iron. Nickel, iron. Chrome alloy, iron. Chrome. Thickness dependence was observed for nickel alloys. The thicker the film, the stronger the action.

  The same result was obtained with a 2-pole 3-type metal plate magnet using a bismuth plate instead of diamagnetic copper. It can be considered that the difference in the ferromagnetic metal determines the chemical action of the magnetic field. The order of stacking is ferromagnetic, diamagnetic, and paramagnetic.

  Two types of three metal plate electrodes in which an iron plate, a copper plate, and an aluminum plate having a thickness in the range of 0.01 to 10 mm are in close contact with each other are formed. The aluminum plate side of these three kinds of metal plate electrodes is arranged facing each other, and a constant voltage, for example, DC 100 V is applied. The space between the electrodes serves as an electric field for reducing action. In the case of three kinds of metal plate electrodes such as a nickel plate, a copper plate, and an aluminum plate, an electric field of oxidative action is obtained. Similarly, iron. Chrome alloy plate or iron. nickel. Three kinds of metal plate electrodes such as a chrome alloy plate, a copper plate and an aluminum plate also generate an electric field of oxidative action. In the periodic table, nickel and chrome are adjacent to each other, centering on iron, and have a common electronic arrangement. This is linked to oxidative action. The same applies to the magnetic field. In addition, an oxidative and reductive electric field can be similarly generated even if an alternating voltage is added. When an electric field is used to treat water, steam, air, and other currents, electromagnetic waves, infrared rays, light, and ultraviolet rays (passing the field at right angles), the state of the treatment object changes. It should be noted that the electric field in which the iron plate side is arranged facing is less effective. Therefore, a two-sided / three-type metal plate electrode in which a diamagnetic metal plate and a paramagnetic metal plate are in close contact with both surfaces of a ferromagnetic metal plate is usually used.

  Change the chemical state and action of water, steam, air and other fluids, currents, electromagnetic waves, infrared rays, light, and ultraviolet rays to be treated using the electric field of the three metal plate electrodes or the magnetic field of the three metal plate magnets. Sometimes the effect can be enhanced by using multiple electric and magnetic fields. In this case, a plurality are arranged in series with the electric field and magnetic field generated by the facing arrangement as units. The object to be processed passes through this electric field or magnetic field sequentially at a right angle. In this case, the polarity of the adjacent electric field or magnetic field is reversed. It is an alternating electric field and an alternating magnetic field. The effect of the electric and magnetic fields shows experimental results proportional to the number of inversions. When creating a magnetic field or electric field with a large opening area, a plurality of 2-pole 3-type metal plate magnets or 2-sided 3-type metal plate electrodes are arranged in parallel.

  Considering the orthogonal relationship between the electric field and the magnetic field, an experiment was conducted on the effect of an electrostatic magnetic field in which the magnetic field of a two-pole / three-type metal plate magnet and the electric field of a two-side / three-type metal plate electrode were arranged orthogonally. The electromagnetic field of the combination of the electric field of the two-sided, three-type metal plate electrode of iron, copper, and aluminum and the magnetic field of the two-pole, three-type metal plate magnet of nickel, copper, and aluminum has an oxidizing action. If the combination is reversed, the electromagnetic field has a reducing action. Iron instead of nickel. Chrome. Even if it changes to nickel alloy, it has an oxidative effect.

  Experiments on the action of electromagnetic fields with parallel and antiparallel electric and magnetic fields have revealed the following. If two types of metal plate electrodes in which an iron plate and a copper plate are in close contact with each other are used, the parallel electromagnetic field has a reducing action even in the electric field between the symmetric positive and negative two electrodes. When the electric field is arranged in parallel to the magnetic field between the NS2 poles, the iron plate surfaces of the two kinds of metal plates are closely stacked on the facing N pole surface and S pole surface. Nickel or iron is used to give an oxidative effect to an electromagnetic field in which the electric and magnetic fields are antiparallel. Chrome. Nickel alloy and copper two metal plate electrodes are used. The method in which the two types of metal plate electrodes are closely attached to the N and S poles on the opposite sides is affected by the leakage magnetic flux. Therefore, the method in which the two kinds of metal plate electrodes are closely stacked on the NS both poles of the magnet and the voltage is added between the two kinds of metal plate electrodes on the opposite side is more stable. This electromagnetic field can be used to bring gas including air, liquid including water, vapor, current, and light into oxidative and reductive states. This fact shows that the asymmetry of the electromagnetic field is related to the asymmetry of the matter wave. Even if bismuth is used as the diamagnetic metal plate, the result does not change.

The invention's effect

  The present invention can be applied to all industrial fields. The water, steam, air, current, and light to be treated are brought into an oxidative state and a reductive state. Since the magnetic and electric fields alone have reductive and oxidative effects, the application range is expanded. It has been confirmed from experiments that the chemical action of the magnetic field and electric field of the three types of metal plates is not easily affected by the shielding effect of the metal. Since it can be attached to the outer periphery of metal piping, construction costs can be greatly reduced. Applications can be greatly expanded.

  The embodiment varies depending on the purpose of use. There are various combinations of individual metals. In the case of a magnetic field, iron, nickel, or iron is used as a ferromagnetic material. Chrome. A combination of nickel alloy, copper or bismuth as the diamagnetic material, and aluminum as the paramagnetic material is practical.

  FIG. 4 is an explanatory view of the magnetic processing apparatus of claim 4. It is an example used for water or steam. Attach so that the water pipe is sandwiched between the N pole face and the S pole face of two 2-pole, 3-type metal plate magnets. The water that has passed through the magnetic field becomes a reducing state. When applied to steam piping, the steam is in a reducing state. It can be replaced with a one-pole / three-type metal plate magnet in which iron, copper, and aluminum plates are in close contact with the opposite N and S pole surfaces, and an iron plate is in close contact with the opposite S and N pole surfaces. Nickel plate, copper plate, aluminum plate 2-pole 3-type metal plate magnets make water oxidative. Promotes chemical reactions in water. Even if an alloy containing iron, chrome and nickel is used instead of nickel, the magnetic field makes the water oxidative. It is the influence of nickel and chrome atoms contained in the alloy.

  The action was confirmed by treating the air with a magnetic field. When air treated with the magnetic field of a 2-pole 3-type metal plate magnet was blown into water, the oxygen solubility increased. The iron, copper, and aluminum dipole / type 3 metal plate magnets are 13 ppm, the nickel, copper, and aluminum dipole / type 3 metal plate magnets are 8 ppm, and the untreated air is 9 ppm. It is thought that oxygen molecules became in a reducing state and the solubility was increased.

  The light emitted by the heating element that has passed through the magnetic field at a right angle, that is, a magnetically processed current, is chemically in two states. This can be confirmed from the difference in production rate and color of iron hydroxide in the water irradiated with light. The magnetic field of iron, copper, and aluminum dipole / three-metal plate magnets is reductive light, nickel, or iron. Chrome alloy or iron. Chrome. The magnetic field of a nickel alloy, copper, aluminum two-pole / three-type metal plate magnet becomes light of oxidative action.

  The light was directly magnetically processed. When it is processed in the magnetic field of a two-pole / three-metal plate magnet of iron, copper, and aluminum, it has a reducing action. Nickel or iron. Chrome. When it is processed in the magnetic field of a two-pole / three-metal plate magnet of nickel alloy, copper, and aluminum, it will be in an oxidative state.

  FIG. 6 shows an example in which two two-sided / three-type metal plate electrodes of iron, copper, and aluminum are arranged facing each other. When a voltage is applied, a reductive electric field is generated between the electrodes. The space has a reducing action when a plurality of the two-sided / three-type metal plate electrodes are installed in parallel in a space having a wide opening area and a voltage is applied. Iron is nickel or iron. nickel. Chrome alloy or iron. Chrome. If replaced with a nickel alloy, the space becomes an electric field with an oxidative effect. Therefore, the state of a large amount of water, steam, and air can be controlled. Current and light conditions can be controlled.

  FIG. 7 shows an example in which the magnetic field between N and S of the two-pole / three-type metal plate magnet made of iron, copper, and aluminum and the electric field between the two-side / three-type metal plate electrodes made of nickel, copper, and aluminum are arranged orthogonally. . The action of the electromagnetic field is oxidative. The effect was confirmed by treating light, current, water, and air. In order to obtain an electromagnetic field of reductive action, the combination of metal plates may be reversed. In the case of the same three-metal plate configuration, the electric field needs to be an asymmetric electric field, for example, an electric field between a positive or negative electrode and a ground electrode. Iron instead of nickel. Chrome. The same tendency occurs even when a nickel alloy is used. Replacing copper with bismuth does not change the trend.

  FIG. 8 shows an example of a parallel electromagnetic field in which the electric field between the positive and negative two poles is arranged in parallel with the direction of the magnetic field between the N and S two poles. If a two-type metal plate electrode in which an iron plate and a copper plate are in close contact with each other is used, an electromagnetic field of a reducing action is obtained. The iron plate surface of the two-type metal plate electrode is brought into close contact with both the N and S pole surfaces of the magnet, and a voltage is applied between the facing electrodes. The effect of the parallel electrostatic magnetic field was confirmed by irradiating the water in the sealed container with the light of the incandescent bulb that received the current processed in this electromagnetic field. The iron plate was replaced with a nickel plate, and an experiment was performed in the same manner using an antiparallel electrostatic magnetic field in which the directions of the electric field and magnetic field were opposite to confirm the oxidative effect. iron. Chrome alloy, iron. nickel. Even if it replaces with a chrome alloy board, it will become an oxidative effect similarly. The same result was obtained using bismuth instead of copper.

  It can be used in various industrial fields. Environmental improvement using water treatment, air treatment, health appliances using reductive magnetic field, oxidative, reductive electric field, magnetic field, chemical reaction catalyst using electromagnetic field, etc.

  It is explanatory drawing of the 2 pole 3 type metal plate magnet of Claim 1.   It is explanatory drawing of the whole surface 3 type metal plate magnet of Claim 2.   It is explanatory drawing of the 1 pole 3 type metal plate magnet of Claim 3.   It is explanatory drawing of the magnetic processing apparatus of Claim 4. (Example 1)   It is explanatory drawing of the 2 surface 3 type metal plate electrode of Claim 8.   It is explanatory drawing of the electric field processing apparatus of Claim 9. (Example 2)   It is explanatory drawing of the electromagnetic field processing apparatus of Claim 10. Example 3   It is explanatory drawing of the parallel (anti-parallel) electromagnetic field apparatus of Claim 11. (Example 4)

Explanation of symbols

1 Magnet 2 Ferromagnetic metal plate (iron plate, iron alloy, nickel)
3 Diamagnetic metal plate (copper, silver, gold, bismuth)
4 Paramagnetic metal plate (aluminum, manganese, platinum)
5 Water piping 6 High voltage power supply

Claims (11)

  Ferromagnetic metal plate with a thickness of 0.01-10 mm on both N and S pole faces of magnet, iron, iron alloy, nickel, cobalt, and diamagnetic metal plate with copper, silver, gold, bismuth Any one of the three types of metal plate magnets in which one of each of aluminum, manganese, and platinum, or a total of three, are placed in close contact with each other as the paramagnetic metal plate, the ferromagnetic metal plate is first in close contact with the magnetic pole surface. A two-pole / three-type metal plate magnet constructed by a method of overlapping and then stacking in close contact with a diamagnetic metal plate and finally a paramagnetic metal plate.   3. A full-surface type 3 metal plate magnet comprising a total of three ferromagnetic metal plates, diamagnetic metal plates, and paramagnetic metal plates in claim 1, each covering the entire surface of the magnet in the order of claim 1.   An iron plate, a copper plate, and an aluminum plate having a thickness of 0.01-10 mm are closely adhered to the N or S magnetic pole surface of the magnet, and an iron plate having a thickness of 0.01-10 mm is closely adhered to the opposite magnetic pole surface. 1 pole 3 type metal plate magnet.   In claim 1, a magnetic field obtained by facing two two-pole / three-metal plate magnets using iron as a ferromagnetic metal plate, copper as a diamagnetic metal plate, and aluminum as a paramagnetic metal plate, A magnetic processing apparatus for water, steam, air, current and light, wherein steam, air, current and light are passed through and magnetically processed.   5. A magnetic processing apparatus according to claim 4, wherein the ferromagnetic metal plate is a nickel plate.   5. The ferromagnetic metal plate according to claim 4, wherein the ferromagnetic metal plate is iron. Chrome. Magnetic processing device made of nickel alloy plate.   7. A magnetic processing apparatus according to claim 4, wherein the diamagnetic metal plate is a bismuth plate.   Ferromagnetic metal plate with a thickness of 0.01-10 mm as iron, iron alloy, nickel, cobalt, diamagnetic metal plate as copper, silver, gold, bismuth, paramagnetic metal plate When three types of metal plates of aluminum, platinum, and manganese are used to form a three-type metal plate electrode, it is always applied to both outer surfaces of the diamagnetic metal plate that is closely adhered to both surfaces of the ferromagnetic metal plate. A two-sided, three-type metal plate electrode in which magnetic metal plates are closely stacked.   The two-sided / three-type metal plate electrodes according to claim 8 are arranged facing each other, and the electric field generated by applying a voltage is treated with an electric field through water, steam, air, current, and light. , Steam, air, current, light electric field treatment equipment.   Iron, nickel, or iron. Chrome. Magnetic field between the north and south poles of a two-pole / three-metal plate magnet made of nickel alloy, copper, and aluminum, iron, nickel, or iron. nickel. Electromagnetic field obtained by passing air, water, steam, current, and light through an electromagnetic field obtained by orthogonally arranging electric fields between two two-sided, three-metal plate electrodes made of chrome alloy, copper, and aluminum. Water, steam, air, current, light electromagnetic field treatment equipment.   Ferromagnetic metal plates such as iron, nickel and iron. Chrome. 2 type 2 type 2 metal plate magnets with 2 types of metal plate electrodes, one of the nickel alloys, 2 types of metal plate electrodes that are stacked with either aluminum, platinum or manganese in close contact as the diamagnetic metal plate. A method of arranging an electric field between two types of metal plate electrodes facing each other and applying a voltage between the two opposing metal plate electrodes and a magnetic field direction between the NS poles in parallel or antiparallel, and an electromagnetic field device based on the method. ,

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