KR102122634B1 - Electromagnetic Field Magnetized Water Device - Google Patents

Abstract

The present invention proposes an electromagnetic field magnetized water receiver that minimizes magnetic field leakage of the working coil and minimizes the distance between the magnetizing unit and the water flowing inside the pipe while minimizing the distance. To this end, the present invention forms a disk surface by increasing the diameter while forming a concentric circle from the center toward the outer periphery of the pair of shielding plates, and a working coil disposed between the shielding plates, and the outer periphery is a flat plate facing the disc surface In addition, at one end and the other end, inlets and outlets are formed, respectively, and are arranged to face the pouch-shaped plate piping and the working coil, which are respectively installed between the disk surface and the shielding plate, and pull the magnetic field projected from the working coil to pull the magnetic field. It is possible to project the plate pipe, it may be configured to include a shielding plate to block the leakage of the magnetic field projecting the plate pipe.

Description

Electromagnetic Field Magnetized Water Device

The present invention relates to a magnetized water receiver, and more particularly, to minimize the leakage of magnetic force projected on flowing water, and improve the magnetization efficiency of water, to a low-power, high-efficiency electromagnetic field magnetized water receiver that can be implemented slim.

The magnetization water heater basically arranges a permanent magnet or an electromagnet around the pipe through which water flows, and the magnetic force projected from the permanent magnet or electromagnetizes the water passing through the piping, and the magnetization efficiency is determined according to the conditions below.

1) The magnetization degree increases as the distance between the magnetic field projecting body projecting the magnetic field and water is close, and when the magnetic field is uniformly projected on the water, the degree of magnetization for water may be uniform.

2) The degree of magnetization increases as the magnetic field loss of the magnetic field projected from the magnetization receiver is small.

3) The larger the contact area between the water flowing through the pipe and the magnetic force, the greater the degree of magnetization.

4) The degree of magnetization increases as the water flowing through the pipe becomes vortex.

Looking at the above conditions, the normal magnetized water is magnetized to treat the water flowing through the pipe by densely arranging permanent magnets or electromagnets around the circular pipe.

This type of piping structure is disclosed in Korean Registered Utility Model 20-0317812. Referring to FIG. 5 of the utility model 20-0317812, it can be seen that water flows into the interior of the circular pipe, and a magnet is disposed on the outer periphery of the circular pipe to apply a magnetic field to the water flowing inside the pipe.

However, the water flowing inside the circular pipe cannot maintain a uniform distance from the magnet due to the structure of the circular pipe, and since the intermediate point and the remote point close to the magnet are distinguished, the water flowing through the pipe is exposed to a uniform magnetic field. Does not work.

Also, referring to FIG. 5 of the utility model 20-0317812, as the pipe is fitted between a pair of magnets, a gap corresponding to the diameter of the pipe is formed between the upper magnet disposed on the upper pipe and the lower magnet disposed on the lower pipe. Occurs. Since the magnetic field projected by the upper and lower magnets leaks from the gap, the degree of magnetization of the water flowing through the pipe must be lowered as much.

For this problem, Republic of Korea Patent Publication No. 10-2012-0135983 has proposed an industrial magnetized water treatment device that increases the magnetic force applied to the pipe by arranging a large amount of magnets around the pipe through which water flows.

Patent Publication No. 10-2012-0135983 arranges a plurality of magnets around the pipe to compensate for magnetic loss, thereby minimizing the reduction in magnetization effect due to magnetic leakage. However, as a result of the experiment conducted by the present applicant, when a plurality of magnets are continuously arranged along a pipe, the magnetization efficiency is not proportional to the increase in the number of magnets, manufacturing difficulties increase, and there is a problem of less practicality.

In addition, referring to FIG. 4 of Patent Publication No. 10-2012-0135983, it can be seen that the central portion of the pipe has a small diameter and both ends have a large shape to form a Bernoulli tube. In this type of pipe, the flow rate of water is limited by the reduction in the diameter of the central portion of the pipe, so in view of this, the actual pipe diameter should be several tens of millimeters (mm) or more.

In addition, there is a problem in that the flow rate of the central portion of the pipe adjacent to the magnetic body and the pipe form the Bernoulli tube is not sufficiently magnetized, and the circular pipe itself is used to leak magnetic fields projected from the upper and lower magnets, so the upper magnet While the number of magnetic materials applied to the and the lower magnet is large, the actual magnetization efficiency cannot be expected. In the actual industrial field, it is a situation that the magnetized water heater of the type proposed in Patent Publication No. 10-2012-0135983 is rarely used.

An object of the present invention is to provide an electromagnetic field magnetization receiver that solves at least one or more of the above-described conventional problems.

The above object is in accordance with the present invention, a pair of shielding plate; A working coil disposed between the shielding plates, forming a disk surface by increasing the diameter while forming a concentric circle from the center to the outer periphery; The outer periphery is a flat plate facing the disk surface, an inlet and an outlet are formed at one end and the other end, respectively, and a pouch-shaped plate pipe is installed between the disk surface and the shield plate, respectively; And a shielding plate disposed to face the working coil, to pull the magnetic field projected from the working coil to cause the magnetic field to project the plate pipe, and to block leakage of the magnetic field projecting the plate pipe. In providing magnetized water.

According to the present invention, the magnetic field leakage can be minimized by combining the flat type piping and the flat type walking coil.

According to the present invention, the distance between the magnetizing unit and the water flowing inside the pipe is uniform and minimized, and thus the optimal magnetization efficiency can be expected.

According to the present invention, water can be formed into a vortex and magnetized to increase the magnetization efficiency of water.

1 and 2 show a conceptual diagram of a magnetization unit according to an embodiment of the present invention.
3 shows the appearance of a prototype developed by the applicant.
Figure 4 shows a reference drawing contrasting the housing and the internal structure of the prototype shown in FIG.
5 shows a structural diagram according to an example of a magnetization unit with a built-in vortex generator.
6 shows a front view, a left side view, a right side view, and a top view among the hexahedral views inside the prototype shown in FIG. 4.
FIG. 7 shows a perspective view of the prototype shown in FIG. 4.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 and 2 show a conceptual diagram of an electromagnetic field magnetization receiver according to an embodiment of the present invention, FIG. 3 shows the external shape of a prototype developed by the applicant, and FIG. 4 shows the housing and interior of the prototype shown in FIG. 3 Referring to the reference drawing in contrast to the structure, FIG. 5 shows a structural diagram according to an example of the magnetization unit with a built-in vortex generator, and FIG. 6 is a front view, a left view, a right view, and a top view among the hexahedral views inside the prototype shown in FIG. FIG. 7 shows a perspective view of the prototype shown in FIG. 4.

Hereinafter, it will be described with reference to FIGS. 1 to 7 together.

First, referring to FIG. 1, the electromagnetic field magnetizer according to the embodiment has a structure in which a pair of plate pipes 101 and 102 are arranged around the flat walking coil 103.

The working coil 103 is formed to be wound so that the diameter increases while forming a concentric circle from the center toward the outer periphery. The working coil 103 forms a surface by a coil wound in the center, which is referred to as a disk surface in the present invention, and is described by giving S1 and S2 as reference numerals.

The disk surface S1 is adjacent to the plate pipe 102 and the disk surface S2 is disposed adjacent to the plate pipe 101. As the working coil 103 is wound, a pair of disk surfaces S1 and S2 and the plate pipes 101 and 102 are disposed adjacent to each other, so that most of the magnetic field projected from the working coil 103 is plate pipe 101 , Projected at 102, and rarely generates a leakage magnetic field projected to other areas except the plate piping 101 and 102.

Plate piping (101, 102) may be formed of a soft synthetic resin, plastic, ABS (Acrylonitrile-Butadiene-Styrene resin), PC (PolyCarbonate),

1) is disposed adjacent to the shield plate 104, 105, or

2) It may be arranged to contact the shield plate (104, 105).

When the plate pipes 101 and 102 contact the shield plates 104 and 105, an eddy current may be formed on the surfaces of the shield plates 104 and 105.

When the eddy current is formed on the surfaces of the shielding plates 104 and 105, and the shielding plates 104 and 105 are in contact with the plate pipes 101 and 102, the eddy current is water flowing inside the plate pipes 101 and 102. An eddy current electric field may be applied to this, which may contribute to an improvement in electrical conductivity of water flowing inside the plate pipes 101 and 102.

The working coil 103 is driven by high frequencies around 20 kHz. When the high-frequency current is conducted, the working coil 103 has a main projection direction of the magnetic field D3 and D3 as shown in FIG. 2 according to the Ampere law in which a magnetic field is formed in a circle around the working coil 103 through which the high-frequency current flows. It becomes D4 direction.

Shield plates 104 and 105 are provided on the outer periphery of the plate pipes 101 and 102 to pull the magnetic field projected from the working coil 103 in the D3 and D4 directions. The shield plates 104 and 105 may be formed of iron, stainless steel, nickel, or a metal material that reacts to a magnetic field. The magnetic field generated by the working coil 103 and projected to the plate pipes 101 and 102 is further pulled by the shield plates 104 and 105 to further reduce the amount of leakage magnetic fields directed in the D5 direction and the D5' direction.

The plate piping 102 is disposed between the shielding plate 104 and the working coil 103 and is disposed on a path of a magnetic field from the working coil 103 to the shielding plate 104.

The plate pipe 102 has a flat plate-shaped surface facing the disk surface S1, and has an empty pouch shape inside for water flow. Therefore, as shown in FIG. 2, its cross section is close to a square shape, and the overall shape is a flat square pouch shape as shown in FIG. Accordingly, the water flowing inside the plate pipe 102 becomes a flat shape and can flow along a large area of the plate pipe 102, and in the disk surfaces S1 and S2 formed by the working coil 103. It can be uniformly and extensively exposed to the projected magnetic field.

The electromagnetic field magnetization water heater according to the embodiment is a magnetic coil generating a magnetic field, unlike the conventional magnetization water flowing through a circular pipe, the distance from the magnetic body is very close, and the plate pipe 102 flows in a flattened state, so the working coil ( 103) has a wide surface facing (Surface) has a high magnetization efficiency and has the advantage of low power and miniaturization. This will be described in detail with reference to Table 1 below.

Referring to Table 1, in the magnetization unit of the present invention (suggestion technology), the gap H1 between the shield plates 104 and 105 and the working coil 103 is smaller than the gap H2 of the magnetization unit according to the prior art. Able to know. In the conventional magnetization unit, since the shielding plate and the working coil are disposed around the circular pipe as shown in Table 1, the diameter of the pipe is determined as the interval H2 between the shielding plate and the working coil. In Table 1, the interval (H1) of the present invention (suggested technology) is smaller than the interval (H2) of the prior art, which reveals that it is not intentionally expressed in order to highlight the features of the present invention.

The plate pipes 101 and 102 according to the present invention have a cross section of a shape close to a rectangle, unlike the conventional circular pipes. Therefore, even if the amount of water flowing into the plate pipes 101 and 102 is the same amount as the conventional circular pipes, the spacing H1 between the shield plates 104 and 105-the working coil 103 uses circular pipes It may be formed smaller than the conventional gap (H2). This will be described with reference to Table 2 below.

As shown in Table 2, the plate piping 101 and 102 of the present invention (suggestion technology) increases the volume by increasing the area S without increasing the height W1 to increase the volume of the water flowing inside. Can be implemented. On the other hand, in the conventional circular pipe, in order to increase the volume per unit length, the radius R must be increased. According to this difference, in order to secure the flow amount of water, the circular pipe of the prior art needs to increase the spacing H2 between the shielding plate and the working coil as shown in Table 1, while the plate according to the present invention (suggestion technique) The pipes 101 and 102 do not need to increase the spacing H1 to increase the flow rate of water. This difference is maximized when the magnetized water is used for industrial or agricultural and fisheries other than household use. When using magnetized water for industrial or agricultural and fisheries, the amount of water to be magnetized per unit time increases significantly, while the radius (R) of a circular pipe according to the prior art must increase significantly, while the magnetization device according to the present invention (suggested technology) does There is no need.

As described through Table 1 and Table 2, when the electromagnetic field magnetized water generator according to the embodiment should increase the amount of water flowing into the plate pipes 101 and 102, the working coil 103 and the shield plate 104, The gap H1 between 105 is hardly increased, and the gap H1 between the working coil 103 and the shield plates 104 and 105 is short, and the working coil 103 faces the shield plates 104 and 105. The strength of the magnetic field is ensured at a very high level. Even if it is the same magnetic field, it is well known to those skilled in the art that the strength of the magnetic field increases as the working coil 103 and the shielding plates 104 and 105 are closer to each other.

Figure 3 shows a prototype picture being developed by the applicant. The applicant has produced a magnetization unit in a structure in which a pair of plate pipes 101 and 102 surround the working coil 103.

As the pair of plate piping 101 and 102 surrounding the working coil 103 has a structure,

1) The thickness of the plate pipes 101 and 102 is formed to be small, thereby reducing the size of the entire case 100a,

2) Since the distance between the working coil 103 and the shielding plates 104 and 105 is small, the strength of magnetic force applied to the plate pipes 101 and 102 is secured, so the working coil 103 and the plate pipes 101 and 102 The size of the and the size of the shielding plates 104 and 105 are reduced.

That is, even under the conditions where the same magnetic force is applied to the electromagnetic field magnetization water purifier according to the present invention and the conventional magnetized water field, the electromagnetic field magnetic field magnet according to the embodiment can project stronger magnetic force to the plate pipes 101 and 102 than the conventional magnetized water receiver.

FIG. 4 shows the housing and internal structure of the prototype shown in FIG. 3.

Referring to FIG. 4 together, the electromagnetic field magnetizer according to the embodiment includes a working coil 103, a plate pipe 101, 102 and a shield plate 104, 105 inside a case 100a, and a plate pipe 101, Inlet pipe 108a for supplying water to 102) and outlet pipe 108b for discharging magnetized water from plate pipes 101 and 102 are provided.

The case 100a may be formed of plastic, ABS (Acrylonitrile-Butadiene-Styrene resin), PC (PolyCarbonate) or formed of a metal material, and the outer periphery of the hole for the inlet pipe 108a and the outlet pipe 108b ( Hole) is formed therein, and there may be provided fixing holes 109a to 109d for fixing a magnetization unit composed of a working coil 103 and plate piping 101 and 102.

In addition, an auxiliary magnetizer 106 may be added between the magnetizing unit and the outlet pipe 108b, and a vortex generator 107 may be added between the inlet pipe 108a and the magnetizing unit. The auxiliary magnetizer 106 may be in the form of arranging a permanent magnet of neodymium between the outlet pipe 108b and the magnetization unit, and add magnetized water by discharging a magnetic field of 3000 to 5000 Gauss toward the outlet pipe 108b side. It can be magnetized. Of course, when considering the magnetization efficiency of the electromagnetic field magnetization receiver according to the embodiment, the auxiliary magnetizer 106 does not necessarily correspond to a required configuration.

The vortex generator 107 is provided with a ball therein, so that water flowing through the inlet 108a collides with the ball to generate a vortex. 4 illustrates that the vortex generator 107 is configured separately from the magnetization unit, the vortex generator 107 may be integrally formed in the magnetization unit. This will be described with reference to FIG. 5.

5 shows a structural diagram according to an example of a magnetization unit with a built-in vortex generator.

Referring to FIG. 5, the magnetization unit according to the embodiment forms a compartment S3 in one region inside the plate pipes 101 and 102, and arranges a ball B in the formed compartment S3 to obtain the inlet pipe 108a ), after the water introduced through the ball (B) collides with the vortex, the plate piping (101, 102) may be magnetized. The compartment S3 may be formed with holes P1 and P2 smaller than the diameter of the ball B while receiving the ball B. The holes P1 and P2 may be provided with water (P1) flowing into the compartment S3 and water P2 used to discharge water from the compartment S3.

6 shows a front view, a left side view, a right side view, and a top view among the six-sided views of the prototype shown in FIG. 4, and FIG. 7 shows a perspective view of the electromagnetic field magnetization receiver shown in FIG.

6 and 7, the distributor 110 is installed on the right side view of the magnetization unit, followed by the inlet 108a-the vortex generator 107, and the distributor is formed in an "U" shape as shown in the top view. The water flowing through the inlet 108a can be distributed to the plate pipe 101 and the plate pipe 102. Unlike the conventional magnetization device, the electromagnetic field magnetization machine according to the embodiment is disposed on both sides of the disk surface formed by the working coil 103, so that the plate pipes 101 and 102 are disposed on each side to minimize magnetic field leakage, and thus flow through the inlet 108a. The water should be divided into two. Since water is supplied to the plate piping 101 and the plate piping 102 through the distributor 110, the plate piping 101 and the plate piping 102 receive the same water pressure from the inlet 108a, which is It means that the flow rates of the plate piping 101 and the plate piping 102 are the same.

The speed of water flowing through the plate pipes 101 and 102 affects the magnetization efficiency, and the magnetization efficiency is maximized when the flow rate is about 2 m/s. However, if the speed of the water flowing through the plate pipe 101 and the plate pipe 102 is different, the degree of magnetization of the magnetized water flowing through the plate pipe 101 and the magnetized water flowing through the plate pipe 102 flows to each other. Can be different. On the other hand, the applicant has made it possible to be magnetized at the same flow rate by supplying water of the same water pressure to the plate pipes 101 and 102 through the "U" shaped distributor 110.

The distributor 110 is used in other fields dealing with fluids in addition to the present invention, but the conventional magnetization device is flat on both sides of the disk surfaces S1 and S2 of the working coil 103 like the electromagnetic field magnetization receiver according to the present invention. Since the plate piping 101 and 102 of the type is not provided in pairs, it is revealed that there is no need for a reason to use the distributor 110 according to the embodiment, and it is used only in the present invention having the plate piping 101 and 102 It is also revealed in advance that it can be.

The distributor 110 divides the water introduced from the inlet 108a into two branches, one of which supplies water to the plate pipe 102 through the first distribution pipe 110a, and the other second distribution pipe ( Water is supplied to the plate pipe 101 through 110b). Therefore, the plate pipe 102 is provided with an inlet 102a and an outlet 102b for connection with the first distribution pipe 110a. Similarly, the plate pipe 101 is provided with an inlet 101a and an outlet 101b for connecting the pipes with the second distribution pipe 110b.

In the above, the electromagnetic field magnetization machine according to an embodiment of the present invention has been described. Applicants have examined the change in physical properties of water by supplying groundwater to the electromagnetic field magnetized water described through the specification, and the test results will be described through Tables 3 and 4 below.

Table 3 shows that the ground water is supplied as raw water to the electromagnetic field magnetized water according to the embodiment, and the electrical conductivity value of water after the magnetization treatment is compared with the electrical conductivity value of the raw water. In Table 3, “No” represents the test round, Immediately after the water passed through the plate pipes 101 and 102 at a flow rate of 2 m or more per second, it was measured nine times in total to obtain an average value.

Since the raw water is groundwater, the electrical conductivity value is slightly different according to the test round, and the average value of the electrical conductivity is 181.37 (us/c). On the other hand, the electromagnetic field magnetization receiver according to the embodiment indicates that the electric conductivity value increases by 6.38 (us/c) compared to the raw water to 187.51 (us/c) on average. In addition, it can be seen that the temperature of the magnetized water is increased by about 0.61 degrees. The temperature is due to the heating of the working coil 103 by applying a high-frequency current of around 20 kHz to the working coil 103, and the increase in the electrical conductivity value is the ionization of water by the electric field and magnetic field generated in the working coil 103 This is a change in physical properties that occurs due to the ionization of magnetized water.

The minerals contained in water are usefully absorbed by aquatic organisms or plants when they are ionized. For example, when cultivating a crop for nutrient solution, the crop absorbs iron or magnesium in the form of divalent iron or trivalent ions, and the absorption rate of iron or magnesium in a non-ionized state is very low. Likewise, the crop absorbs other minerals in an ionized form, and the supply of an ionized form of minerals is also recommended in nutrient solution cultivation.

Next, Table 4 shows the experimental results of measuring the surface tension of water after the raw water (groundwater) was magnetized while flowing through the plate pipes 101 and 102.

Table 4 compares the surface tension of raw water (groundwater) and magnetized water, and indicates that the surface tension of raw water is 57.214 (dyne/cm) compared to 61, 469 (dyne/cm). .

Water exists in a state in which a plurality of water molecules are aggregated, and the aggregate of water molecules is commonly referred to as a cluster. Before the magnetization treatment, the cluster of water molecules of the raw water has a large volume and the surface tension has a large value in proportion to the cluster size. On the other hand, since the electromagnetic field magnetization receiver according to the embodiment ruptures the water molecules by the electromagnetic field projected by the working coil 103, it can be seen that the cluster of water molecules becomes smaller, and thus the surface tension decreases.

As described above, the electromagnetic field magnetization water purifier according to the embodiment changes the physical properties of water, such as electrical conductivity and surface tension, even if water flowing at a flow rate of 2 m/s or more passes briefly through the plate pipes 101 and 102. Shows. The electromagnetic field magnetization machine according to the embodiment increases the magnetization efficiency to increase the size of the working coil 103 or to induce a good change in physical properties compared to a conventional magnetization device without significantly increasing the power applied to the working coil 103.

This reduces the distance between the working coil 103 and the shielding plates 104 and 105 as the working coil 103 and the plate pipes 101 and 102 are implemented in a flat plate shape, and is applied to the plate pipes 101 and 102. The paper utilizes a feature that increases the strength of the magnetic field.

101, 102: plate piping 101a, 102a: inlet
101b, 102b: outlet 103: working coil

Claims (7)

A pair of shield plates;
A working coil disposed between the shielding plates, forming a disk surface by increasing the diameter while forming a concentric circle from the center to the outer periphery; And
The outer periphery is a flat plate facing the disk surface, an inlet and an outlet are formed at one end and the other end, respectively, and a pouch-shaped plate pipe is installed between the disk surface and the shield plate, respectively; And
It is disposed facing the working coil, to pull the magnetic field projected from the working coil to allow the magnetic field to project the plate pipe, and a shielding plate to block leakage of the magnetic field projecting the plate pipe; Electromagnetic field magnetization handset. According to claim 1,
The plate piping,
Consists of a first plate piping and a second plate piping respectively installed on both sides of the disk surface,
An electromagnetic field magnetization receiver, characterized in that the working coil is disposed between the first plate pipe and the second plate pipe to form a magnetization unit. According to claim 2,
The shield plate is composed of a pair,
An electromagnetic field magnetization receiver, characterized in that the magnetization unit is disposed between the pair of shielding plates. According to claim 2,
The first plate piping and the second plate piping each include a first inlet and a second inlet,
The first inlet and the second inlet are jointly connected to the U-shaped distributor, the electromagnetic field magnetized water receiver characterized in that to receive the water flowing in from the outside at the same water pressure. According to claim 1,
The plate piping,
An electromagnetic field magnetized water receiver, which is made of synthetic resin and applies eddy current formed in the shielding plate to the flowing water in contact with the shielding plate. delete delete

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