KR200401282Y1 - Magnetizing apparatus - Google Patents

Abstract

The present invention can easily obtain the N-pole treated magnetized water, and the magnetization strength by applying DC electric current to the liquid magnetizer and the liquid of the magnetizer that can change the magnetization performance according to the user's intention by controlling the current supplied to the coil. The present invention relates to a device for increasing the magnetization time and extending the magnetization holding time. A magnetization device for achieving the object of the present invention includes a liquid magnetization device for obtaining a magnetized liquid by applying magnetism to a flowing liquid, the inlet and outlet including: And a flow pipe made of a non-magnetic material forming a flow channel through which the liquid flows into the inlet and flows out through the outlet port, a coil wound on the outer circumferential surface of the flow pipe, and a hollow cylindrical conductive pipe respectively coupled to the inlet and the outlet of the flow pipe. It is configured to include, by generating a magnetic field in the flow pipe by applying a DC current to the coil and the conductive pipe, respectively At this time, the S stimulus is formed on the inlet side of the water flow pipe, and the direction of the current applied to the coil and the current applied to the liquid of the flow pipe is determined to form the N stimulus on the discharge side. It is a useful design having the effect of changing the magnetization performance according to the user's intention by adjusting the current supplied to the magnetization device configured as described above.

Description

Magnetization Processing Unit {MAGNETIZING APPARATUS}

The present invention relates to a liquid magnetization apparatus, and more particularly, it is possible to easily obtain a liquid such as N-pole treated magnetized water, and to change the magnetization performance according to the user's intention by adjusting the current supplied to the coil and the liquid. It relates to a liquid magnetizer.

In general, magnetized water uses the principle that the water molecules become smaller as the oxygen and hydrogen bonds of the water molecules undergo separation and recombination when water moves through a powerful magnetic field. As well as the sterilization function is increased, the water molecule size is small, so the absorption of the body increases, and has the function to smoothly excrete the waste accumulated in the body.

In particular, as reported in the Journal of the American Medical Association (JAMA), v82, pages 621-624, 1990, water treated at the north pole inhibits the proliferation of cancer cells, but is treated at the south pole. Is not known to inhibit cancer cell proliferation at all. Experiments show that the surface tension of water at the north pole of the magnet is increased while the surface tension of water at the south pole is decreased. In other words, an increase in the surface tension of water means an increase in the viscosity of the water, which means that the structure of the water has changed densely. In other words, when the structure of water becomes dense by the N pole of the magnet, it has the effect of suppressing the proliferation of cancer cells. When the structure of water is loosened by the S pole of the magnet, the cancer cells proliferate.

In the conventional magnetization apparatus for obtaining such magnetized water, it is common for the liquid to act only on the flow channel or the water pipe through which the magnetic field is generated by the permanent magnet or the electromagnet.

For example, "Korean magnetization structure" of Korean Patent Application No. 2004-0014499 refers to "a structure in which a magnetizing water pipe is spirally wound on the outer circumferential surface of a permanent magnet having a shape such as a circular rod or a circular ring", and a Korean patent application No. 2002-0008621 "Magnetic water generator" is a "magnetized water generator, characterized in that the spiral wound on the outer peripheral surface of permanent magnets," Korean Patent Application No. 2004-0097786 "magnetizing device" is "coil is a synthetic resin, ebonite, A magnetic field is formed inside the coil when AC or DC low voltage high frequency power of about 0.5 ~ 5V is applied to a magnetizer wound in a cylindrical pipe of excellent corrosion resistance and non-magnetic material such as FRP, Bakelite, stainless steel, and titanium. When passed through, water is magnetized to a small group of water ". Further, U.S. Patent 5,584,994 discloses that the pure water discharged from the pure water tank 9 by the pump 27 is recovered by the circulation channel 37 again, and a magnetic generator in the middle of the channel 37 is shown. 31 is provided, and the magnetic force generator 31 discloses a magnetized water production apparatus having a structure in which a permanent magnet is provided such that three channels are disposed between the permanent magnets, and a magnetic force generator used therein.

However, as described above, sufficient time is required to magnetize water passing through the magnetic field in which permanent magnets or electromagnets are generated, and the magnetization maintenance period of the magnetized liquid does not last forever. I can't.

Therefore, the present invention is to solve the above problems of the prior art, an object of the present invention is to coil the coil on the outer periphery of the water pipe, the S magnetic pole is formed in the inlet side region of the water pipe and the N magnetic pole in the outlet side region By applying a direct current to the coil so that the formation of such a liquid can easily obtain a liquid such as N-pole treated magnetized water, and to adjust the current supplied to the coil to change the magnetization performance according to the user's intention will be.

Another object of the present invention is to provide a liquid magnetization apparatus capable of increasing the magnetic flux density in the flow channel in the flow channel to magnetize the liquid flowing in the flow channel with better efficiency.

Liquid magnetizing device according to the present invention for achieving the above object, the inlet and outlet, the liquid inlet and the inlet is formed of a non-magnetic material to form a flow path flowing out through the outlet;

A coil wound on an outer circumferential surface of the flowing pipe;

It comprises a hollow cylindrical conductive pipe respectively coupled to the inlet and outlet of the water pipe,

A magnetic field is generated in the flowing pipe by applying direct current to the coil and the conductive pipe, respectively.

The S-pole is formed at the inlet side of the water inlet, the direction of the current applied to the coil is determined to form the N-pole at the outlet side, and the anode (+) of the DC power is coupled to the outlet at the inlet conductive tube of the inlet. The negative (-) pole of the DC power supply is connected to the conductive pipe, or only the positive (+) or the negative (-) is connected to the conductive pipe of the discharge port when a minute current flows through only the single pole of the DC power supply.

In the case of drinking water, the current flowing through the anode of the conductive tube may ionize the metal, which is the conductive tube, so that the metal ion is energized with a microcurrent so that the metal is not detected in the drinking water more than necessary. If gold, silver, zinc, tin, manganese, magnesium, etc. are needed, it should be made of materials that are beneficial to the human body.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a perspective view illustrating a liquid magnetizer according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of the liquid magnetizer of FIG. 1.

As shown, a flow pipe 10 is provided to form a flow path 16 through which liquid such as water flows in a direction (arrow direction) from one end 12 (inlet) to the other end 14 (outlet). The flowing pipe 10 has a cylindrical shape and is formed of a nonmagnetic material such as a plastic material such as polyvinyl chloride resin. The inlet 12 and the outlet 14 of the water pipe 10 are pipe-shaped conductive pipes 22 each made of a conductive material (for example, gold, silver, brass, stainless steel, etc.) that is harmless to a human body. , 24) are inserted and joined. The conductive tubes 22 and 24 are provided so that a direct current (DC) current may be supplied with electricity. The positive electrode of the DC power supply is connected to the conductive tube 22 coupled to the inlet 12, and the negative electrode of the DC power supply is connected to the conductive tube 24 coupled to the outlet 14. have.

The coil 26 for electrons is wound on the outer periphery of the flowing pipe 10 over almost the entire length of the flowing pipe 10. The coil 26 is made of a conductive wire such as a copper wire coated with an insulating material (not shown), and is provided so that a direct current electric current is supplied with electricity. The positive pole of the DC power source is connected to one end 26a of the coil 26 positioned on the inlet 12 side of the water pipe 10, and the coil 26 located on the outlet 14 The other end 26b is connected with a negative (-) pole of the DC power supply. When a DC current is applied to the coil 26, an S stimulus is formed on the inlet 12 side of the flowing pipe 10, and an N stimulus is formed on the outlet 14 side to form a magnetic field in and around the flowing pipe 10. The coil 26 is wound in an appropriate direction. Compared with the conventional magnetization apparatus using only permanent magnets, the present invention has a feature that the magnetization performance can be changed as intended by the user by adjusting the amount of current supplied to the coil by using an electromagnet composed of the coils 26.

In addition, compared to the conventional magnetization processing apparatus in which a magnetic field is formed inside the coil by applying a DC or AC power supply of about 0.5 to 5 V to a coil wound on a non-magnetic cylindrical pipe, and passing water through the coil. The polarity of the magnetic field flowing through the pipe can be clearly distinguished according to the flow of current only, and additional direct current is applied directly to the liquid flowing in the pipe so that the liquid is affected by the additional magnetism according to the electricity flowing in the liquid. The direct current flowing through the conductive tube is characterized by ionizing the conductive tube.

Hereinafter, the operation effect of the liquid magnetization device according to the present invention configured as described above will be described taking magnetization water as an example.

By applying a DC current to the coil 26 surrounding the water pipe 10, an S-pole is formed at the inlet 12 side of the water pipe 10, and an N-pole is formed at the outlet 14 side. (10) Magnetic fields are formed in and around. For convenience of explanation, the region S from the inlet 12 to the intermediate point of the flowing pipe 10 is called the S stimulus zone, and the region N from the intermediate point to the outlet 14 is called the N stimulus zone. Therefore, the water flowing through the inlet 12 of the flowing pipe 10 and passing through the flow path of the S stimulus zone S gradually passes through the flow path of the N stimulus zone N.

Furthermore, in the present invention, in order to maintain the magnetization of water for a long time by making the strength of magnetization stronger, in the present invention, the conductive pipe 22, which is coupled to the inlet 12 and the outlet 14 of the water pipe 10, 24) apply a DC current by connecting the positive and negative poles respectively. As a result, electricity flows through a liquid such as water flowing in the oil channel 16 in the oil pipe 10, and a direct current magnetic field flowing in the opposite direction (that is, the direction from the outlet 14 to the inlet 12). Influence of the influence on the liquid in the oil channel 10 increases the magnetic flux density in the oil channel 16 so that the liquid flowing in the oil channel 16 can be magnetized with better efficiency. That is, by applying a direct current to the coil as described above, the magnetic flux density in the cylindrical coil is increased, thereby magnetizing the liquid flowing in the flow channel more strongly.

As described above, the present invention forms an N magnetic pole N on the outlet 14 side of the flowing pipe 10 by applying a DC current by winding the coil 26 on the flowing pipe 10, and at the same time, the flowing pipe ( The direct current is also applied to the conductive tubes 22 and 24 coupled to both ends of 10) to increase the magnetization efficiency of the liquid so that the liquid is N-pole treated, and the N pole magnetized property can be retained for a longer period of time. have. Of course, it is also possible to obtain the magnetized water magnetized to the S pole by changing the direction of the DC current as needed.

Conditions such as the diameter of the water pipe 10, the flow rate of water, the amount of current, the size of the coil 26 and the number of windings can not be specifically limited, and the long term depending on the strength of the degree of magnetization according to the purpose of using the magnetized water Various combinations are formed through experience or experiments.

In addition, as the conductive pipes 22 and 24 coupled to the inlet 12 and the outlet 14 of the flowing pipe 10, silver is known to have the effect of sterilizing, absorbing and blocking harmful wavelengths such as electromagnetic waves and water waves. In addition, it is possible to use a conductor such as gold known to have an effect such as promoting blood circulation due to the ionic action, which can be selected and used in various ways depending on the purpose of use of the magnetized water based on the inherent efficacy of these materials.

3 is a perspective view showing a liquid magnetization device according to another embodiment of the present invention.

As shown, the flow pipe 30 is spirally wound on the outer circumferential surface of the permanent magnet 46, which is a single rod or a plurality of permanent magnets are combined to form a long rod shape. The flowing pipe 30 has a cylindrical shape and is formed of a nonmagnetic material such as a plastic material such as polyvinyl chloride resin.

The inlet 32 and the outlet 34 of the water pipe 30 each have a pipe-shaped conductive tube 42 made of a conductive material (for example, brass, stainless steel, gold, silver, etc.) that is harmless to a human body. 44) are inserted and joined. The conductive pipes 42 and 44 are provided so that direct current (DC) electricity is supplied with electricity. The positive electrode of the DC power supply is connected to the conductive pipe 42 coupled to the inlet 32, and the negative electrode of the DC power supply is connected to the conductive pipe 44 coupled to the outlet 34. have. Since the operation and effect by the energization of the DC current through the conductive pipes 42 and 44 are the same as described above, the description thereof is omitted.

When the permanent magnet 46 is provided as a single permanent magnet, the S pole of the permanent magnet 46 is disposed in the region corresponding to the inlet 32 side of the water pipe 30, the discharge port 34 side In the region corresponding to the N pole of the permanent magnet 46 is disposed. This is to obtain magnetized water magnetized to the N pole as described above. On the other hand, the permanent magnet 46 is provided in the form of a plurality of permanent magnets bonded to each other by mutual magnetic force, even when the liquid is equally affected by the north pole and the south pole while passing through the water flow pipe (34) The magnetized water magnetized to the N pole can be obtained through the magnetic flow of DC electricity additionally introduced into the side conductive tube.

As described above, the water passing through the flowing pipe 30 is provided in a spiral wrap around the outer periphery of the permanent magnet 46 can secure a sufficient magnetization time to receive the magnetic force of the permanent magnet 46 There is a characteristic that complete magnetization is possible.

In the above, it has been described as an example of the N-pole treated magnetized water that can be used for human drinking in general by using water as the liquid to be magnetized. Of course, it can be magnetized by the magnetization method using the same.

For example, the outlet 24 of the magnetizer shown in FIG. 1 is connected to the inlet 32 of the magnetizer shown in FIG. 3, or conversely, the outlet 34 of the magnetizer shown in FIG. It may be magnetized by connecting to the inlet 12 of the magnetization device shown in.

Although this invention was demonstrated concretely by the said embodiment, this invention is not restrict | limited by this, The deformation | transformation and improvement are possible within the range of common knowledge of a person skilled in the art.

Hereinafter, the effects of the present invention will be described in more detail through Examples and Experimental Examples.

Example

Purified water was passed through an inlet of the liquid magnetizer according to the present invention shown in FIGS. 1 and 3 to obtain N-pole treated magnetized water.

Experimental Example 1

Proven that water is magnetized to a single pole (N pole) and retained for a long time

In general, two people, known to be trained to move the weight according to the magnetic energy waves of permanent magnets and electromagnets, were commissioned as follows.

That is, in order to show the movement according to the magnetic fields of permanent magnets and electromagnets, a conductor metal such as gold, silver, and copper is hung in a silk thread to form a weight. Hold the weight with your right hand on the permanent magnet and electromagnet where the magnetic field flows, and turn it further clockwise on the N pole of the magnet, counterclockwise on the S pole, and add it in the middle region of the N pole and S pole. It was confirmed that the return movement back and forth between the N-pole and S-pole. Although there is no theoretical basis for the different movement direction according to the magnetosphere, it is the result of a trained person for many years, and it is a premise experiment to determine the accuracy through this.

The magnetized water and the non-magnetized water according to Example 1, that is, purified water before passing through the magnetization apparatus according to Example 1, were prepared in five beakers each containing the same amount of water, and no indication was made. In the absence of state (only the test client can be distinguished), the trained experimenter was allowed to experiment with the degree of magnetization.

In addition, a beaker containing the magnetized water and the non-magnetized water was placed in a refrigerator, and the same experiment was performed for the degree of magnetization after 12 hours and 20 days.

As a result, the magnetized water and the non-magnetized water of N pole were accurately distinguished from each of the two experimenters, which were the same immediately after the magnetization treatment and after 12 hours and 20 days. In other words, in the case of magnetized water, all the experiments resulted in the same clockwise rotation as that of the N magnetic energy wave. In addition, the water that is not magnetized by the electric alternating current wave of the refrigerator (wave energy in which the north pole and the south pole of the pole constantly exchange) appears as water stored in the north pole and the south pole at the same time, and moves back and forth like a clock. On the other hand, it was observed that the water discharged to the N pole through the magnetization treatment device continued to rotate clockwise.

Experimental Example 2

Demonstrate the problem and solution of the existing technology of short magnetization period

The magnetization degree was measured by the characteristic test of water in the same manner as in Experimental Example 1. The case of applying DC electric current to the conductive tubes of FIGS. 1 and 3 is the result of Experimental Example 1, and the case of not applying DC electric current to the conductive tube is Experimental Example 2. When no direct current was applied to the conductive tube, both 1 and 3 additionally stopped rotating clockwise within 10 seconds.

Experimental Example 3

In the same manner as in Experimental Example 1, respectively, the same amount of magnetized water and the purified water immediately before the magnetization treatment were placed in five beakers, respectively, and each contained a rose flower.

As a result, it was observed that the rose of the beaker containing the magnetized water in the N pole was fresh even after 7 days, whereas the rose of the beaker in the non-magnetized beaker decreased significantly after 4 days.

As described above in detail, the liquid magnetization device according to the present invention winds a coil on the outer periphery of the flow pipe forming the flow channel, and an S-stimulus is formed in the inlet side region of the flow-through tube and an N-pole is formed in the outlet side region. By applying a direct current to the coil as possible, the N-pole treated magnetized water can be easily obtained, and the magnetization performance can be changed as intended by the user by adjusting the current supplied to the coil.

Further, in addition to the magnetic field generated by the electromagnetic force generated by applying a DC current to the coil or the magnetic field generated by the permanent magnet, further comprising a conductive tube through which a DC current is energized at both ends of the flowing pipe, the liquid flowing inside the flowing pipe is directly It is intended to be influenced by magnetism, which has the effect of magnetizing with a better magnetization efficiency.

It provides a very simple structure while maximizing the magnetization effect.

1 is a perspective view showing a liquid magnetization device according to an embodiment of the present invention,

2 is a cross-sectional view of the liquid magnetizer of FIG.

3 is a perspective view showing a liquid magnetization device according to another embodiment of the present invention,

4 is a block diagram showing a conventional magnetization apparatus.

<Explanation of symbols for the main parts of the drawings>

10,30: water pipe

12,32: inlet

14,34: outlet

22,24,42,44: Conduit

26: coil

46: permanent magnet

Claims (2)

In a liquid magnetizer for obtaining a magnetized liquid by applying magnetism to a flowing liquid, A permanent magnet having a long rod shape by combining single or plural permanent magnets; An inlet and an outlet, wherein an inlet and outlet are formed to flow through the outlet and outflow through the outlet, and the outlet pipe being spirally wound around the outer circumferential surface of the permanent magnet; It includes a hollow cylindrical conductive pipe coupled to the inlet and outlet of the water pipe, respectively And applying a direct current to the conductive tube to generate a magnetic field in the flowing pipe together with the magnetic force of the permanent magnet. The liquid magnetization apparatus of claim 1, wherein a negative (-) pole of a DC power source is connected to a conductive pipe coupled to the outlet of the water pipe.