KR101256949B1 - Magnetizer activated in the north pole for the benefit of human bodies - Google Patents

Abstract

The present invention relates to an N pole-activated magnetization processor, according to an aspect of the present invention, a hollow case having an inlet formed on one side and an outlet formed on the other side, and each S pole region inside the case. It includes a pair of permanent magnets that are in close contact with the inner surface of the case and the N-pole regions are in contact with each other to form a space portion inside the case, the space portion has a boundary plate along the point where the magnetic force of each of the permanent magnets is zero It is formed so as to face each other, the N-pole activated magnetization processor is characterized in that the water flowing into the inlet of the case flows only between the boundary plate to be affected only by the N pole region of the permanent magnet.

Permanent Magnet, N-pole, Magnetized Water

Description

MAGNETIZER ACTIVATED IN THE NORTH POLE FOR THE BENEFIT OF HUMAN BODIES}

The present invention relates to a magnetization processor in which the north pole is activated, and more particularly, the magnetization water magnetized by the north pole can be easily obtained by allowing the north pole to be activated by a simple structure. The present invention relates to a magnetizer having excellent effect.

In modern times, many households, factories, farms, and other wastes are emitted, and as time passes, water with self-cleaning capacity is severely polluted and cannot be directly used as drinking water. It is a well known fact that many ecosystems are damaged.

In addition, many devices and methods have been used as a water purification process to clean contaminated water, and research for more efficient water purification is still being conducted.

Looking at some of the known methods of purified water to date, the biological method using the active sludge or microorganism, the chemical method using the chemical reaction, and the physical method using the electron or ultrasonic waves or the situation is being studied.

However, according to the conventional water purification method, not only stable water purification is achieved but also operating costs required for water purification are high, and water purification efficiency cannot be increased.

In other words, conventional biological methods using activated sludge or microorganisms are used in many countries internationally to decompose contaminants by microorganisms, but since they have a limit of effective concentration in digestive substances of microorganisms, they contain high concentrations of waste. In the state, the treatment is insufficient, and in the case of waste water having alkali or acidity, pretreatment is required, and it is affected by the environment such as time and temperature, and the installation area must be large. there was.

In addition, the chemical treatment method has the advantage of fast reaction speed and simple process, while even in the case of decomposing organic materials which are difficult to treat biologically, the installation and maintenance costs are too expensive to treat wastewater by itself. B was used only as a post-treatment.

In addition, the physical method using electrons or ultrasonic waves is applied to the process of decomposing hardly decomposable substances such as benzene compounds and halogen compounds, which are difficult to process by biological methods or chemical methods, but they are widely used because their effects are insignificant compared to the huge facility and maintenance costs. There was a disadvantage that can not be.

In order to improve this point, a magnetization apparatus using a permanent magnet has been conventionally disclosed.

The water treated by the magnetizer is called magnetized water, which does not mean that the water itself is magnetic, and the arrangement of water molecules is changed by the magnetic field to form a water molecule structure different from that of ordinary water. Refers to the water in a state transformed into an unusual structure. However, these characteristics cannot be maintained continuously, and are maintained for a certain period of time and then returned to their original state.

The magnetic field lines of the magnetic field extend out of the N pole to the S pole. When water, which is an electrical conductor, passes through such a magnetic field in a direction perpendicular to each other, an electromotive force is generated at a right angle with respect to the direction of the magnetic force line, so that a microcurrent flows and electrons flow in the opposite direction. This electron flows by the force of the flowing water.

Water molecules usually stick together and form clusters. In the low energy state, it becomes a large cluster, so the kinetic energy is low. In the formation of strong magnetic energy, water molecules are positively and positively polarized and oxygen atoms of negative polarity are attached to each other, causing the movement of rotation, stretching, vibration, etc. At this time, as the molecular cluster (cluster) value of the water molecules decreases, adjacent clusters pull together to form a structure. That is, the water molecules cause movements such as rotation, stretching, and vibration while passing through the magnetic field by the magnet, and the clusters of the water molecules become particulates and are activated.

In other words, the magnetization device uses the principle that the water molecules become smaller as the oxygen and hydrogen bonds undergo a process of separation and recombination when water moves through the magnetic field. The water molecules can be refined and sterilization effects can be obtained. It is a device to get the effect of being able to remove scale or rust.

Therefore, when water passes through the magnetic field of the magnet, the molecular structure of the water is ion-activated to become magnetized water having a weak alkaline hexagonal structure rich in minerals. The magnetization device using such a magnet can obtain a large amount of magnetized water in a short time. It can be widely used as household water in many fields such as food factory and bath, livestock and plant cultivation as well as in general household.

The prior art related to such a magnetization device is disclosed in Korean Patent Utility Model Publication No. 0437393, "A magnetization hexagonal water production apparatus using a magnetizer." According to this, the surface tension of water is changed by magnetic action of water, so that various minerals contained in the water can be useful for the human body. The permanent magnet (12000 gauss) with high magnetic strength is used to N pole, S pole and S pole are arranged to be spaced apart from each other through spacers to increase magnetic field strength and magnetic flux density, and the raw water circulating water is passed through the magnetizer. It was made to be possible.

However, according to recent research, Magnetism and its effects on the living system, Albert Roy Davis, 1974, the magnetized water generated at the N pole of a magnet While there is a beneficial effect, the magnetized water produced in the S pole has been found to have a generally detrimental effect. Specifically, the magnetized water generated at the N pole of the magnet is beneficial to the human body, such as increasing work efficiency, suppressing cancer cell proliferation, improving metabolism, reducing pain, calming allergy and promoting sleep.

In view of these findings, the above prior art has the disadvantage that the beneficial effect on the human body is reduced because magnetization water is generated in the same way as the N pole in the S-pole, which is harmful to the human body.

The present invention has been made to solve the problems described above, an embodiment of the present invention relates to a magnetization processor capable of obtaining the N pole number by a simple structure, maximizing the magnetization processing efficiency.

According to an aspect of the present invention, a hollow case having an inlet formed on one side and an outlet formed on the other side thereof, and each S pole region in the case is in close contact with the inner surface of the case, and the N pole regions It includes a pair of permanent magnets provided to abut the space portion is formed inside the case, the space portion is formed so that the boundary plate facing each other along the point where the magnetic force of each of the permanent magnets is 0, An N pole activated magnetization processor is provided, wherein water flowing into an inlet flows only between the boundary plates so that it is affected only by the N pole region of the permanent magnet.

According to an embodiment of the present invention as described above, first, the permanent magnet is provided inside the case, and the water flowing inside the case can be easily obtained by moving only the region where the N pole of the permanent magnet acts. have.

Second, water can flow through both sides of the permanent magnet to increase the magnetization efficiency.

Third, the N pole is formed in the central portion of the permanent magnet, it is possible to double the size of the magnetic field by the N pole, thereby increasing the magnetization efficiency.

Fourth, the water flowing in the magnetization processor can repeatedly pass through the central portion of the permanent magnet having the largest magnetic force, it is possible to provide a sufficient rotational force for the separation of water molecule particles.

1 is a perspective view showing a magnetization processor activated N-pole is beneficial to the human body according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing a magnetization processor.

3 is a cross-sectional view showing the permanent magnet shown in FIG.

The magnetization processor 1 according to an embodiment of the present invention has a hollow case 10 having an inlet 11 formed at one side thereof and an outlet 12 formed at the other side thereof, and each of the inside of the case 10. The pair of permanent magnets 20 is provided with the S-pole area closely contacting the inner surface of the case 10 and the N-pole areas contact each other so that a space portion (not shown) is formed inside the case 10. Including a space, the boundary plate 30 is formed to face each other along the point where the magnetic force of each of the permanent magnets 20 is zero, the water flowing into the inlet 11 of the case 10 is bounding plate By only flowing between 30, it is influenced only by the N-pole region of the permanent magnet 20.

The present invention corresponds to an apparatus for obtaining magnetized water, and in particular, corresponds to an apparatus for obtaining an N pole number magnetized by an N pole of a magnet. As described above, in the magnetized water treated by the magnet, the characteristics by the N pole and the S pole are many different from each other, and in the case of water magnetized by the N pole, the viscosity increases and the surface tension increases. do. As a result, the structure of the water can be increased, and an environment in which the proliferation of cancer cells can be suppressed can be provided, and metabolic activity can be improved, and beneficial effects such as reduction of pain can be obtained.

The magnetization processor 1 according to the present invention is largely composed of a permanent magnet 20 for magnetizing water and a case 10 formed to surround the permanent magnet 20.

The case 10 may be formed to completely surround the permanent magnet 20, but is not limited thereto. If only the magnetic force according to the N pole by the permanent magnet 20 may act on the water therein, It may be formed in a form of wrapping a portion of the permanent magnet 20.

The inlet 11 and the outlet 12 are formed in the case 10 and correspond to the inlet and the outlet of the magnetized water. That is, except for the inlet 11 and the outlet 12, there is no passage through which water enters from the case 10.

As shown in FIG. 2, the case 10 may have a form in which the upper case 10a and the lower case 10b are coupled to each other.

The permanent magnet 20 may be formed as a normal permanent magnet (永久 磁石, permanent magnet). The material of the permanent magnet 20 is formed of a large coercive force as well as a large residual magnetic force as opposed to a material having a high permeability, and may be made of tungsten steel, chromium steel, or KS steel. , MK steel, alumino (alloy of aluminum nickel cobalt copper), new KS steel, Qunipe (alloy of copper nickel nickel iron) and the like.

The permanent magnet 20 may be made in the form of a conventional bar magnet, and as described below, may be made in the same form as when two bar magnets are combined. The portion of the permanent magnet 20 that is biased in the direction in which the N pole, that is, the line of magnetic force, is called the N-pole region 21, and the portion of the permanent pole 20 that is inclined in the direction in which the line of magnetic force is entered, is called the S-pole region 22. In the case of dividing the permanent magnet 20, one side becomes the N-pole region 21, and the other side becomes the S-pole region 22.

The permanent magnet 20 is provided in the case 10, and the water flowing in the case 10 flows through the N-pole region 21. That is, as described above, when the permanent magnet 20 is divided into the N-pole region 21 and the S-pole region 22, water to be magnetized is allowed to flow in contact with the N-pole region 21. do. In this case, the influence of the magnetic force by the S-pole region 22 cannot be excluded at all, but since it flows in contact with the N-pole region 21, the water is mostly treated by the magnetic force by the N-pole to obtain N-pole number. It becomes possible.

4 is a cross-sectional view taken along line AA ′ of the magnetization processor shown in FIG. 1.

In the magnetization processor 1 according to a preferred embodiment of the present invention, the permanent magnet 20 is located in the center of the case 10, the water introduced through the inlet 11 is the permanent magnet 20 of the It is made to move in two directions.

In addition, the permanent magnet 20 is formed with an upper surface 23 and a lower surface 24 in contact with water, the permanent magnet 20, the upper surface 23 and the lower surface 24, respectively It is made to be magnetized to form a line of magnetic force in the upward or downward direction.

The permanent magnet 20 is located in the center of the inside of the case 10, and thus spaces are formed in both the upper and lower sides of the permanent magnet 20 in the case 10, so that both sides of the permanent magnet 20 are formed. Water can split and move.

The permanent magnet 20 is formed to fit within the case 10 except for a space in which water moves in the case 10. Water passing through the inlet 11 is made to directly enter the upper surface 23 and the lower surface 24 of the case 10, in other directions, such as the left and right sides of the permanent magnet 20 It cannot be moved.

The permanent magnet 20 is formed in the form of a rod magnet having a relatively wide shape, and the inlet 11 and the outlet 12 are formed in a direction forming the boundary between the N pole region 21 and the S pole region 22. It is formed to follow the direction connecting. The N pole region 21 is formed to be relatively long so that water introduced through the inlet 11 can continuously move in the N pole region 21, and thus the permanent magnet 20 is relatively in the pole direction. It is short and relatively long in the pole and vertical direction.

The permanent magnet 20, like the conventional permanent magnet 20, one side may be formed in the form of the N pole, the other side of the S pole, as will be described later, the center of the N pole, the edge of the S pole form It may be made of.

The upper and lower surfaces in the N-pole region 21 of the permanent magnet 20 are the upper surface 23 and the lower surface 24, respectively, and water flowing along the upper surface 23 and the lower surface 24 is Move. The permanent magnet 20 is preferably made in the form of up and down symmetry, is located in the center of the case 10 is made to be able to efficiently magnetize the water moving up and down.

In the permanent magnet 20, a line of magnetic force comes out of the N-pole region 21 and a line of magnetic force enters the S-pole region 22. Assuming that one side is in the form of a normal magnet composed of the north pole, and the other is the south pole, and considering only the lines of magnetic force in the N pole region 21, the lines of magnetic force are generally in a direction perpendicular to the surface. Or in a direction biased to the S-pole region 22. In addition, magnetic force lines are formed in the direction perpendicular to the surface at the end portion of the N-pole region 21, which is the portion of the greatest magnetic force.

As a result, the magnetic force acting on the water passing through the upper surface 23 and the lower surface 24 in all cases is formed in a direction perpendicular to the general direction of movement of the water, and can strongly act on the magnetization treatment.

In addition, by moving the water through both the upper surface 23 and the lower surface 24 of the permanent magnet 20 can further improve the magnetization treatment efficiency.

FIG. 5 is a plan view showing a partial configuration of the magnetization processor 1 shown in FIG. 2.

In the magnetization processor 1 according to the preferred embodiment of the present invention, the permanent magnet 20 is formed so that the N pole is formed at the center and the S pole is formed at both the left and right sides, and the magnetic force is zero in the permanent magnet 20. At the two points, the boundary plate 30 is formed to face each other so that water flows only between the boundary plate 30.

In addition, a plurality of partition walls 40 are formed between the boundary plates 30 so that water flows in a zigzag.

In addition, the partition wall 40 is formed in a direction substantially perpendicular to the boundary plate 30, and water flowing between the boundary plates 30 repeatedly passes through the center of the permanent magnet 20 having a maximum magnetic force. It is done to be.

The connecting portion of the boundary plate 30 and the partition wall 40 may be formed in a vertical shape, but preferably made thicker than the peripheral portion for smooth flow of water. That is, it is preferable to form a gentle arc shape at the connection part of the said partition board 30 and the partition 40.

One side of the permanent magnet 20 is not formed in the form of the N pole, the other is the S pole, the center is formed of the N pole, the left and right both sides are formed in the form of the S pole. That is, the two permanent magnets 20 are formed in the same form as the opposite to the N pole.

The permanent magnet 20 may be formed by combining two magnets, respectively, but preferably formed integrally.

The permanent magnet 20 is manufactured using an alloy which is a raw material of the magnet, mainly an alloy of aluminum, nickel, cobalt and iron, which is called Alnico. The alloy is melted, placed in a mold and cooled, and placed inside an electromagnetic field with a strong magnetic field during the cooling process. Accordingly, as the alloy to be cooled is hardened, each atom constituting the alloy is aligned in the magnetic field direction and a permanent magnet 20 is formed.

In the case of the permanent magnet 20 according to the preferred embodiment of the present invention, the molten alloy is not formed as a single mass but is formed by two separate molten alloys. In other words, the molten alloy is injected into each mold of the same type, and the cooling process is performed. The electromagnetic fields acting on each alloy are formed in opposite directions. .

The permanent magnet 20 is manufactured in such a form so that the N pole region 21 is formed in the middle of the long, and the S pole is formed in both the left and right sides. Since the middle N-pole region 21 is actually formed by combining two N-pole regions 21, the magnetic force in the N-pole region 21 is doubled by the mutually repulsive force, and a larger magnitude of magnetic force is obtained. Can be.

In the permanent magnet 20, the boundary between the N pole region 21 and the S pole region 22 is formed at two portions, and the magnetic force becomes zero at this boundary point. The boundary plate 30 is formed at this point, the boundary plate 30 is in close contact with the permanent magnet 20 to form a constant space. The boundary plate 30 may be integrally formed with the case 10, and may be separately formed.

The boundary plate 30 is formed on both the upper surface 23 and the lower surface 24.

In the case of the permanent magnet 20 in which the N pole region 21 is formed at the center, the largest magnetic force is generated in the center portion of the N pole region 21, and the greatest influence on water is generated in this portion, The ability to provide large torque can have an effective effect on segmentation.

The partition wall 40 is formed in a direction perpendicular to the boundary plate 30, one end of which is in close contact with the left boundary plate 30, and the other end of which is opposite to the right boundary plate 30. It is made in the form of water so that the water passing through it can be moved in a zigzag form.

Accordingly, the water moving between the boundary plates 30 can move in the N-pole region 21 for a relatively long time so that the magnetic force is continuously applied, and the center of the magnetic field in the N-pole region 21 is the largest. The part can be repeatedly moved from side to side, so that a strong rotational force can be repeatedly operated.

That is, the magnetic force at the point where the boundary plate 30 is formed is the weakest. When the water particles move at the point passing the central point of the N-pole region 21, a strong magnetic force is applied to the water particles. It is possible to provide a large rotational force to, and by repeating this process it is possible to facilitate the atomization of water particles and further improve the magnetization efficiency.

1 is a perspective view showing a magnetization processor activated N-pole is beneficial to the human body according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing a magnetization processor,

3 is a cross-sectional view showing the permanent magnet shown in FIG.

4 is a cross-sectional view taken along line AA ′ of the magnetization processor shown in FIG. 1;

FIG. 5 is a plan view illustrating some components of the magnetization processor illustrated in FIG. 2.

Description of the Related Art [0002]

1: magnetization processor 10: case

10a: upper case 10b: lower case

11: inlet 12: outlet

20: permanent magnet 21: N pole area

22: S pole region 23: upper surface

24: lower surface 30: boundary plate

40: bulkhead

Claims (6)

A hollow case having an inlet formed on one side and an outlet formed on the other side; And And a pair of permanent magnets provided on the inside of the case so that the respective S pole areas are in close contact with the inner surface of the case and the N pole areas are in contact with each other, such that a space is formed in the inside of the case. The space portion is formed such that the boundary plates face each other along the point where the magnetic force of each of the permanent magnets is zero, so that water flowing into the inlet of the case flows only between the boundary plates, so that only the N-pole region of the permanent magnet is present. To be affected, A plurality of partitions are formed between the boundary plates so that water flows zigzag. The permanent magnet is located in the center of the case and the space is formed on both the top and bottom of the permanent magnet, N-pole activated magnetization processor, characterized in that the water flowing through the inlet is moved to be divided into the upper and lower sides of the permanent magnet. delete delete The method according to claim 1, The partition wall is formed in a direction perpendicular to the boundary plate, and the water flowing in the zigzag between the boundary plate to pass through the portion where the N-pole regions of the permanent magnet of the maximum magnetic force is in contact with each other repeatedly Magnetizer with pole activated. delete delete

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