JP2001321775A - Fluid modifying apparatus employing magnetic hydrodynamic theory, magnetic repulsion theory and excitation action due to far infrared rays - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for rationally utilizing magnetism and far infrared rays. SOLUTION: Flat piping 1 is used as a strong magnetic field forming means in order to reduce the opposed interpole distance between permanent magnets 2 and the cross-sectional area of the piping is reduced at the same time to increase the flow velocity in the piping to enhance magnetic hydrodynamic effect. Magnetic circuits are formed on the rears of the permanent magnets 2 not only to concentrate all of the magnetomotive forces of the permanent magnets to the formation of a magnetic field in the piping but also to prevent the deterioration of the permanent magnets with the elapse of time to semipermanently keep the life thereof. Pole pieces are mounted on the permanent magnets to concentrate magnetic flux to a narrow region to form a magnetic field high in flux density to enhance magnetic hydrodynamic effect. The periphery of the piping is filled with far infrared emitting ceramics to emit far infrared rays using the circumferential temperature as drive force to reflect the same from the inner surface of a cover and the reflected far infrared rays are concentrated to the piping to supply far infrared energy to a fluid efficiently to excite the motion of the molecules to activate the fluid.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention belongs to the technical field of providing a fluid reforming apparatus for preventing or removing rust, corrosion, scale, etc., from water pipes, drain pipes, hot water pipes, etc. .

[0002]

2. Description of the Related Art Conventionally, an electrode is provided in a pipe for the purpose of reforming water to flow an electric current, or two or more kinds of metals are provided in a pipe to utilize a difference in metal ionization tendency. (Principle of the voltaic battery) A substance that has a piezo effect, such as tourmaline, is generated in a pipe by generating a weak current, and water is ionized. A coil is wound around the pipe to flow current, and a permanent magnet is attached to the pipe. There are several devices on the market, such as a method of generating a weak magnetic current in water by the principle of electromagnetic induction by forming a magnetic field in a pipe and passing water through the pipe. These all apply the principle of flowing a weak current through a fluid to ionize the fluid or decompose the molecular groups, but are not designed engineeringly, and the calculated results are not expected. Lack reliability.

[0003]

Since many of the conventional techniques involve a method of disposing foreign matter in pipes and bringing them into contact with water, there are many problems in using them in facilities such as drinking water. In particular, leaching of aluminum or the like may be suspected as a cause of circulatory disease or impairment of brain function. In the method of disposing a permanent magnet outside the pipe or winding the coil around the pipe, there is no fear that foreign matter will dissolve in the water, but since the magnet and coil are arranged far away from the pipe, a strong magnetic field desired throughout the pipe Is less reliable to form. The method of arranging magnets, electrodes, and tourmaline in the pipes requires cutting the pipes for construction.

[0004]

The principle of fluid reforming by magnets is the electromotive force generated inside the fluid by electromagnetic induction generated when the fluid passes through the magnetic field, so it is important to first create a strong magnetic field and The purpose is to increase the flow velocity of the passing fluid. "FIG. 4" is a cross-sectional view showing the essential points of the apparatus of the present invention. As shown in the figure, by making the pipe flat, the cross-sectional area of the pipe becomes smaller and the flow velocity becomes faster. Further, by flattening the pipe, the distance between the S pole and the N pole of the permanent magnets installed opposite to each other with the pipe interposed therebetween is short, and a stronger magnetic field can be secured. Further, by forming a magnetic circuit that connects the back surfaces of the two magnets, it is possible to prevent the loss of the performance of the magnet due to the leakage of magnetic flux, so that all of the capabilities of the mounted magnet can be injected into the magnetic field between the S pole and the N pole.
Furthermore, if the inside of the cover including the pipe and the magnet magnetic circuit is filled with a ceramic (for example, silica black) having a high far-infrared radiation characteristic and the far-infrared rays are concentrated on the pipe, the far-infrared energy passes through the inside of the pipe. In the case of water, when the molecular interaction of the fluid is activated to disintegrate the molecular group of the fluid, in the case of water, the water molecular group (cluster) is decomposed and reformed into water having high permeability. In the case of fuel oil such as petroleum, atomization and gasification are more complete, so that combustion efficiency is improved, fuel efficiency is improved, and exhaust gas is cleaner. As shown in FIG. 5, the magnetic flux is concentrated in a narrow range by using a magnetic pole piece shaped to concentrate the magnetic flux on a permanent magnet sandwiching a flat pipe to increase the magnetic flux density and at the same time the fluid cuts the magnetic field ( Care is taken to minimize the time (passing through the magnetic field) to maximize the magnetohydrodynamic effect.

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described with reference to examples. First example When an ordinary steel pipe or stainless steel pipe is pressed and flattened to 40% of the outer diameter (up to 2.4 cm for an outer diameter of 6 cm), the internal cross-sectional area becomes the cross-sectional area of the original pipe. Since the flow rate is reduced to about 1/2, the flow rate is doubled. A permanent magnet is attached to this flat part with an N pole,
When the south pole is attached to the opposite side, the distance between both poles becomes 2.4 cm. The distance between both poles is 6c when installed in the original piping as it is
m, the distance between the poles is 1 / 2.5. That is, the strength of the magnetic field obtained between the two poles becomes 2.5 times. The effect of magnetohydrodynamics is inversely proportional to the time the fluid cuts off the magnetic flux and proportional to the amount of magnetic flux.
A doubling of the flow rate by a factor of five means that the magnetohydrodynamic effect is increased by a factor of five. As shown in Fig. 4, the permanent magnet mounted on the pipe is connected from the back of each permanent magnet to the back of the opposing magnet with a material with high magnetic permeability to complete the back magnetic circuit and control the leakage of magnetic flux to the minimum. As a result, the magnetic flux generation function of the permanent magnet can be efficiently concentrated on the magnetohydrodynamic effect, and at the same time, the deterioration of the permanent magnet over time is minimized and the performance of the magnet is maintained semipermanently . Second example As shown in "Fig. 6", ceramics filled in the space inside the cover (the space surrounding the piping) emits far-infrared rays by driving the ambient temperature as driving force. Since a reflecting mirror that focuses on the center of the lens is formed, far-infrared rays concentrate on the pipe without waste and activate the fluid. Third Example As shown in FIG. 5, by attaching a pole piece of a special shape to a permanent magnet, the magnetohydrodynamic effect can be doubled, so that the effect can be created accurately even at low flow rates. Fourth Example Even in the case of an existing pipe, a pipe made of a material having malleability, such as a steel pipe, can be mounted by pressing the pipe at the existing site, so that the pipe can be mounted without cutting or changing the pipe.

The gist of the present invention is to improve the flow velocity by flattening the piping, to reduce the distance between magnetic poles by flattening the piping, to prevent the leakage of magnetic flux by the configuration of the backside magnetic circuit of the permanent magnet, and to realize the permanent magnet. To prevent the deterioration of magnetic flux over time, promote the activation of fluid by energetic excitation of fluid molecules by filling with far-infrared radiating ceramics, mount magnetic pole pieces on permanent magnets to concentrate magnetic flux in a narrow area and reduce magnetic flux density It is possible to freely design the reforming content of the fluid by combining the five principle principles of increasing the electromagnetic induction effect by increasing it. Existing pipes can be maintained without requiring any work such as cutting pipes or changing pipe routes.

[Brief description of the drawings]

FIG. 1 is a plan view of a standard installation of the present invention.

FIG. 2 is an elevation view of a standard installation of the present invention.

FIG. 3 is a side view of a standard installation of the present invention.

FIG. 4 is a cross-sectional view taken along a line AA in a standard installation of the present invention.

FIG. 5 is a cross-sectional view when a pole piece is mounted in a standard installation of the present invention.

FIG. 6 is a cross-sectional view when a ceramic is filled in a standard installation of the present invention.

[Description of code] is a flattened pipe is a permanent magnet, a yoke member that forms a magnetic circuit, a vault that connects yoke materials that form a magnetic circuit, and a long nipple that adjusts the distance between the yoke materials that form the magnetic circuit is permanent The pole piece that concentrates and induces the magnetic flux of the magnet is the back magnetic circuit of the permanent magnet The cover is the filled ceramic layer

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Claims (5)

[Claims] The present invention relates to a fluid which enhances the effect of electromagnetic induction by increasing the flow rate by increasing the flow rate by reducing the cross-sectional area in the pipe by flattening the pipe through which the fluid passes, thereby enhancing the reforming effect of the fluid. Reformer 2. A fluid reforming apparatus using a permanent magnet in which a magnetic circuit is provided on the back surface of a permanent magnet externally arranged so that the N and S poles face each other with a flat pipe interposed therebetween to prevent leakage of magnetic flux. 3. A fluid reforming apparatus using a permanent magnet, which employs a method of increasing the magnetic field strength by reducing the distance between poles of a permanent magnet mounted outside the pipe by flattening the pipe. 4. A ceramic is filled so as to surround a pipe in a space inside a cover provided outside a magnetic circuit provided on the back of a permanent magnet, and far infrared rays emitted from the ceramic are guided to a fluid passing through the inside of the pipe. Fluid reformer that reforms fluid by exciting fluid molecules with infrared energy 5. A permanent magnet mounted on the outside of the piping with the piping interposed therebetween is provided with a magnetic pole piece for concentrating magnetic flux in a narrow range, thereby concentrating the magnetic flux in a narrow range to increase the magnetic flux density to increase the magnetic fluid dynamics. Reformer for use with enhanced effect