KR950008663A - Fireproofing method of hydrocarbon fuel, fuel reforming device, magnetic stamping device, magnetic resonance device, magnetizer, magnetization treatment method and chemical reaction control method - Google Patents

Abstract

A method of combustion of a hydrocarbon-based fuel which resonates and absorbs photoene energy in primary dissociation means, cleaves and dissociates hydrocarbon molecules into free radicals, and further splits and dissociates free radicals by nuclear resonance in secondary dissociation means. If the reshielding energy of the tertiary dissociation means is absorbed resonantly, it can be maintained for a long time due to the dissociation and dissociation of individual reactors. The magnetic field of the static magnetic field generated in the opening of the magnetic field to which the subject moves is formed in a gradient phase, and is automatically induced in the resonance zone corresponding to the chemical shift of the magnetic resonance without changing the frequency of the applied high frequency magnetic field. Magnetic scavenging device to form a static magnetic field, hydrogen compound, etc. to form a static magnetic field to be automatically induced in the resonance zone corresponding to the chemical shift of nuclear magnetic resonance on the subjects such as hydrogen compounds A magnetic resonance device using the magnetic postmarking device which causes magnetic resonance such as nuclear magnetic resonance and electron spin resonance to be performed on a to-be-tested object. The reaction speed, parallelism, and the like can be easily controlled by adjusting a magnetizer through which magnetic fluid flows in the plurality of ferromagnetic fields, the strength of the ferromagnetic field, and the passage distance of the oily fluid.

Description

Fireproofing method of hydrocarbon fuel, fuel reforming device, magnetic stamping device, magnetic resonance device, magnetizer, magnetization treatment method and chemical reaction control method

Since this is an open matter, no full text was included.

1 is a schematic cross-sectional view showing the configuration of an apparatus used in the practice of the method of the present invention;

4 is a diagram showing an infrared resonance absorption wavelength of a hydrocarbon fuel;

7 is a schematic cross-sectional view showing the configuration of a fuel reforming apparatus used in the practice of the present invention;

10 is a perspective view showing a part of the magnetic stamping device of the third embodiment of the present invention;

18 is a longitudinal sectional view of the magnetizer of the present invention.

Claims (49)

A method of combusting a hydrocarbon-based fuel, the method of combusting a hydrocarbon-based fuel by resonance absorbing a photoene group and a magnetic group and dissociating and dissociating each atom, and then contacting and bonding with oxygen. The combustion method of a hydrocarbon-based fuel according to claim 1, wherein the primary energy dissociates and dissociates each free radical by resonating hops with photoene, and the nuclear dissociation is also carried out by secondary absorption to further dissociate and dissociate atoms. 3. The combustion method of a hydrocarbon fuel according to claim 2, wherein the tertiary dissociation resonates and absorbs photoene energy to the hydrocarbon fuel in the secondary dissociation state. The combustion method of a hydrocarbon fuel according to claim 2, wherein infrared rays having a wavelength of 3 to 4 탆 are used for the primary dissociation. The combustion method of a hydrocarbon fuel according to claim 2, wherein the nuclear magnetic resonance of the secondary dissociation uses a magnetic field of 3500 gauss or more and 15 megahertz or more in a proportional water content relationship of 234.87 gauss / megahertz. 4. The combustion method of a hydrocarbon fuel according to claim 3, wherein infrared rays of 6 to 8 mu m are used for secondary dissociation. The combustion method of a hydrocarbon fuel according to claim 3, wherein visible light or ultraviolet light is used for primary dissociation. The combustion method of a hydrocarbon fuel according to claim 3, wherein visible light or ultraviolet light is used for tertiary dissociation. The combustion method of a hydrocarbon-based fuel according to claim 1, wherein the primary dissociation resonates and absorbs photoenergy to dissociate the free radicals, and the secondary dissociation and resonant absorption of the electron box energizes to split and dissociate atoms. 10. The combustion method of a hydrocarbon fuel according to claim 9, wherein the tertiary dissociation resonates and absorbs photoene energy in the hydrocarbon water fuel in the secondary dissociation state. The combustion method of a hydrocarbon fuel cell according to claim 9 or 10, wherein visible light is used for secondary dissociation. The combustion method of a hydrocarbon fuel according to claim 9 or 10, wherein ultraviolet light is used for primary dissociation. The combustion method of a hydrocarbon fuel according to claim 10, 11, 12, wherein infrared rays of 6-8 mu m are used for tertiary dissociation. Primary dissociation means for resonantly absorbing photoenergy in a hydrocarbon-based fuel to perform primary dissociation to dissociate into a free radical; And secondary dissociation means for performing secondary dissociation to dissociate and dissociate atoms by resonating magnetic energies with the primary dissociated hydrocarbon fuel. 15. The fuel reformer of claim 14, further comprising tertiary dissociation means for reconstructing the secondary dissociated hydrocarbon-based fuel and tertiary dissociation to resonate the photoenergy. 15. The fuel reformer of claim 14, wherein said primary dissociation means has infrared irradiation means for irradiating a hydrocarbon fuel with infrared rays. 15. The fuel reformer of claim 14, wherein the primary dissociation means has visible light irradiation means for irradiating visible light to a hydrocarbon fuel. 15. The fuel reformer of claim 14, wherein the primary dissociation means comprises ultraviolet irradiation means for irradiating ultraviolet light to hydrocarbon fuel. 15. The apparatus of claim 14, wherein the secondary dissociation means comprises a magnetic field of 3500 gauss or more. A fuel reformer having means for generating a high frequency of 15 megahertz or more. 15. The fuel reformer of claim 14, wherein the secondary dissociation means comprises means for forming a magnetic field of 3000 gauss or more, and means for generating microwaves of 8 gigahertz or more. The fuel reforming apparatus according to claim 15, wherein the tertiary dissociation means includes a flow passage means for flowing hydrocarbon fuel and a heater attached to an outer circumference of the flow passage means. The fuel reformer of claim 21, wherein the flow-through means is a pipe made of ceramics. The fuel reformer of claim 21, wherein the flow-through means is a pipe made of carbon. 24. The fuel reformer according to claim 22, 23, further comprising control means for controlling a heating temperature of said heater so that the temperature of said flow-through means is in the range of 93 to 206 캜. In a magnetic stamping device corresponding to a painting shift when a magnetic resonance is to be performed on a moving subject, a magnetic stamp configured to form a magnetic field of a static magnetic field generated at an open portion of a moving path of the subject in a gradient phase. Device. The magnetic sweep device according to claim 25, wherein the gradient of the magnetic force of the static magnetic field is sequentially opened from the upstream side of the subject to the downstream side. 27. The magnetic scrubbing device according to claim 25, wherein a gradient of the magnetic force of the static magnetic field is sequentially closed from a moving upstream side of the subject to a downstream side. 26. The magnetic scrubbing device according to claim 25, wherein a gradient of the magnetic force of the static magnetic field is sequentially opened from the moving upstream side of the subject to the central part to be maximized at the central part, and is sequentially closed downstream from the central part. The magnetic sweep device according to claim 25, wherein a gradient shape of the magnetic force of the static magnetic field is formed by changing the distance between the open portions of the magnetic path in accordance with the moving direction of the subject. 26. The magnetic sweeping device according to claim 25, wherein a gradient shape of the magnetic force of said static field is formed by changing the thickness of the magnetic circuit forming said magnetic path in accordance with the direction of movement of said subject. A magnetic stamp device corresponding to a chemical shift when causing magnetic resonance to move a moving object, comprising: a magnet; And a yoke connected to the magnet so as to form a magnetic path having an open portion in the middle thereof, wherein the to-be-revolved object is moved to the open portion of the magnetic path, and the thickness of the yoke is changed according to the moving direction of the to-be-resonated object. Self-marking device. A magnetic stamp device corresponding to a chemical shift when causing magnetic resonance to move a moving object, comprising: a magnet; And a yoke connected to the magnet to form a magnetic path having an open portion in the middle thereof, wherein the to-be-revolved body moves to the open portion of the magnetic path, and the length of the open portion of the magnetic path is in the direction of movement of the to-be-resonated body. So changing, the magnetic sweep device. A magnetic resonance apparatus for performing magnetic resonance on a moving subject, comprising: magnetic field forming means for forming a static magnetic field whose intensity changes in a moving direction of the subject; And means for applying a high frequency electromagnetic field of a constant frequency to the subject to be resonated. 34. The magnetic resonance apparatus of claim 33, wherein the magnetic field forming means comprises the magnetic sweep device of claim 1. 34. The magnetic resonance apparatus of claim 33, wherein the magnetic resonance is a magnetic resonance selected from the group consisting of nuclear magnetic resonance and electron spin resonance. The magnetic resonance apparatus of claim 33, wherein the to-be-resolved object is a liquid of a hydrogen compound. A magnetic resonance apparatus for causing magnetic resonance to be performed on a moving object, comprising: a magnet; A yoke connected to the magnet to form a magnetic path having an open portion halfway; A conduit installed in succession to the opening of the furnace, the conduit through which the subject is moved; A high frequency oscillation amplifier for oscillating structured wave electromagnetic waves of a certain constant frequency; And a high frequency oscillation coil which is connected to both ends of the high frequency oscillation amplifier and wound around the conduit, wherein the thickness of the yoke is changed in accordance with the moving direction of the subject. 38. The magnetic resonance apparatus of claim 37, wherein the magnetic resonance is a magnetic resonance selected from the group consisting of nuclear magnetic resonance and electron spin resonance. 38. The magnetic resonance apparatus of claim 37, wherein the subject is a liquid of a hydrogen compound. A magnetic resonance apparatus for causing magnetic resonance to be performed on a moving object, comprising: a magnet; A yoke connected to the magnet to form a magnetic path having an open portion halfway; A conduit installed in succession to the opening of the furnace, the conduit through which the subject is moved; A high frequency oscillation amplifier for oscillating a high frequency electromagnetic wave of a constant constant frequency; And a high frequency oscillation coil connected at both ends to the high frequency oscillation amplifier and wound around the conduit, wherein the length of the open portion of the magnetic path is changed in accordance with the moving direction of the subject. 41. The magnetic resonance apparatus of claim 40, wherein the magnetic resonance is a magnetic resonance selected from the group consisting of nuclear magnetic resonance and electron spin resonance. 41. The magnetic resonance apparatus of claim 40, wherein the to-be-resolved object is a liquid of a hydrogen compound. A magnetizer for magnetizing magnetic fluid, comprising: a first magnetic member; A magnet sandwiching the first magnetic member; A second magnetic member surrounding the first magnetic member and the magnet; And a flow path disposed in the magnetic field formed by the first magnetic member, the magnet, and the second magnetic member, through which the magnetic fluid to be magnetized flows. The magnetizer according to claim 43, wherein the flow path is disposed by reciprocating the inside of the magnetic field a plurality of times. In the magnetizer for magnetizing the magnetic fluid, a plurality of places are steep, and the first magnetic member having a hysteresis characteristic with small residual magnetization is sandwiched by a magnet, and the sharp portions of the first magnetic member are different from each other. Two magnetic blocks adapted to be poles or in-phase poles; A second magnetic member surrounding the magnetic block and having hysteresis characteristics with small residual magnetization; And a flow path disposed in the magnetic field formed by the magnetic block and the second magnetic member, through which a magnetic fluid to be magnetized flows. 46. The magnetizer according to claim 45, wherein the flow path is provided by reciprocating the inside of the magnetic field a plurality of times. A magnetization processing method comprising magnetizing a magnetic fluid material by flowing a magnetic fluid material having a free molecule having an accessory electron in a magnetic field, and controlling the spin direction of the accessory electron of the free molecule. 48. The magnetization treatment method according to claim 47, wherein the magnetic fluid material is a hydrogen compound which is vitrified by resonance absorption of photoenergy. A chemical substance excited by resonance absorption of photoenergy is allowed to flow through the ferromagnetic field, and the ratio of free radicals is regulated in the spin direction of the incident electrons of the free radicals to adjust the incidence rate of the free molecular molecules. Chemical reaction control method, characterized in that for controlling the chemical reaction. ※ Note: The disclosure is based on the initial application.