KR200437393Y1 - Magnetization hexagonal water manufacturing device using magnetizer - Google Patents

Abstract

The purpose of the present invention is to change the surface tension of the water by magnetic action of the molecular structure of the water, various minerals contained in the water can be useful to the human body, using a permanent magnet (12000 gauss) with high magnetic strength The N and S poles are arranged at regular intervals through spacers to increase the strength and magnetic flux density of the magnetic field, and the hot water circulating water is passed through the magnetizer to change the magnetization hexagonal number with low surface tension of the circulating water. It is to provide a magnetized hexagonal water production apparatus.

Magnetization hexagonal water manufacturing device using magnetizer

Description

Apparatus for producing magnetized hexagonal water using a magnetizer {omitted}

1 is a longitudinal sectional view of a magnetization hexagonal water production apparatus using a magnetizer according to an embodiment of the present invention,

FIG. 2 is an exploded perspective view of FIG. 1.

<Description of the code | symbol about the principal part of drawing>

50: round permanent magnet 50a: through hole

52: circular spacer 52a: through hole

54: long bolt 54a, 54b: screw part

56a, 56b: Nut 60: Cylinder

62a, 62b: screw part 64: left connection member

65: right connecting member 64a: piping

64b: Screw part 64c: Inlet

65a: Piping 65b: Screw part

65c: outlet 70: support bracket

70a: center through hole 72: ring

74: connecting member 76: through hole

The present invention relates to an apparatus for producing magnetized hexagonal water using a magnetizer. In particular, the surface tension of the water is changed by magnetic action of the molecular structure of the water so that various mineral components contained in the water can act effectively on the human body. Magnetized hexagonal channel with small surface tension of circulating water through the water by increasing the intensity of magnetic field and magnetic flux density by arranging N pole and S pole at regular intervals through spacers using permanent magnets ranging from 12,000 gauss to 13,000 gauss. It relates to a magnetized hexagonal water production apparatus using a magnetizer that can be changed.

The magnetizer, which has been widely used in the past, is installed by installing a pipe between the magnets of the north pole and the south pole of the magnet to allow water to pass through and change the polarity of the water molecules by the magnetic force passing between the north pole and the south pole to adsorb iron powder. Although it was used for the purpose of preventing the problem, it did not show the results and there was a problem that only the hot water circulator, such as half body bath, only circulating hot water without a magnetization device.

Therefore, the present invention has been made to solve the above various problems, the object of the present invention is to change the surface tension of the water by magnetic action of the molecular structure of the water various minerals contained in the water can act effectively on the human body An object of the present invention is to provide a magnetization hexagonal water production apparatus using a magnetizer for changing the magnetization hexagonal water.

Another object of the present invention is to use the permanent magnet (12000 gauss) with high magnetic strength to arrange the N pole and the S pole through spacers to increase the strength and magnetic flux density of the magnetic field so that the hot water circulating water passes through the magnetizer. It is to provide a magnetized hexagonal water production apparatus using a magnetizer that can be changed to a magnetized hexagonal number of the surface tension is small.

In order to achieve the above object, the magnetic field strength of the present invention is 12,000 gauss to 13,000 gauss, a circular spacer of a nonmagnetic material thinner than the permanent magnet, and a penetration formed in the center of the circular permanent magnet and the circular spacer, respectively. Long elongated bolts passing through the holes and alternately inserting the circular permanent magnets and the circular spacers, respectively, and the elongated bolts so that the water passing through the magnetic continuity generated in the circular permanent magnets in a perpendicular direction changes into the magnetization hexagonal number. A pair of nuts respectively screwed into the threaded portions formed on both sides of the elongated bolts to fix the circular permanent magnets and the circular spacers alternately inserted into the bolts, and the circular permanent magnets respectively inserted into and supported by the elongated bolts. And a stainless circle containing the circular spacer A through hole for supporting both ends of the elongated bolts and allowing water to pass through the sieve and the cylindrical bolts to be fixed concentrically in the cylindrical body, and a pair of support brackets having a central through hole formed at the center thereof, respectively. A stainless steel cylinder for accommodating the circular permanent magnets alternately inserted, the circular spacer, a pair of nuts screwed into the threaded portions formed at both ends of the elongated bolt, and the support brackets respectively supporting the left and right sides of the pair of nuts. And a left and a right connecting member which are respectively joined to the threaded portions formed on both outer peripheral surfaces of the cylindrical body, each having an inlet for introducing water and an outlet for discharging the introduced water. .

Hereinafter, a magnetization hexagonal water production apparatus using a magnetizer according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a longitudinal cross-sectional view of a magnetization hexagonal water production apparatus using a magnetizer according to an embodiment of the present invention, Figure 2 is a perspective view showing an exploded view of FIG.

As shown in Figure 1 and 2 is a magnetized hexagonal water production apparatus using a magnetizer according to an embodiment of the present invention is a circular permanent magnet 50 having a magnetic strength of 12,000 gauss to 13,000 gauss, and the permanent magnet 50 The circular permanent magnet 50 and the circular spacer 52 made of a thinner nonmagnetic material and through the through holes 50a and 52b respectively formed in the center of the circular permanent magnet 50 and the circular spacer 52. The elongated bolts 54 alternately inserting the circular spacers 52 and the elongated bolts so that the water passed through the magnetic continuity generated in the circular permanent magnets 50 in a perpendicular direction changes into the magnetization hexagonal number. A pair of screws respectively screwed to the threaded portions 54a and 54b formed on both sides of the elongated bolts 54 so that the circular permanent magnets 50 and the circular spacers 52 alternately inserted into the 54 are fixed. Nuts 56a and 56b, Stainless steel cylindrical body 60 for receiving the circular permanent magnet 50 and the circular spacer 52 respectively inserted and supported in the elongated bolt 54, and fixed in the cylindrical body 60 concentrically To support both ends of the elongated bolts 54 and through holes 76 through which water is formed, a pair of support brackets 70 having a central through hole 70a formed in the center and the long A pair of nuts 56a screwed into the circular permanent magnets 50 and the circular spacers 52 alternately inserted into the bolts 54 and the threaded portions 54a and 54b formed at both ends of the elongated bolts 54, respectively. 56b) and the cylindrical cylindrical body 60 made from stainless steel which accommodates the said support bracket 70 which supports the left and right sides of the said pair of nuts 56a and 56b, respectively, and the outer peripheral surface of the both sides of the cylindrical body 60, respectively. An inlet 64c which is screwed into the formed threaded portions 62a and 62b and into which water is introduced and A is composed of a discharge port (65c) for discharging to the outside are formed, respectively left and right connecting members (64,65).

The left connecting member 64 has a screw portion 64b formed on an outer circumferential surface of the pipe 64a extending to one side so as to be connected to a water supply pipe (not shown), and the right connecting member 65 has a water supply pipe (not shown). The screw part 65b is formed in the outer peripheral surface of the piping 65a extended to one side so that connection is possible.

The support bracket 70 includes a ring 72 having a central through hole 70a formed at the center thereof, and a connecting member 74 supporting and connecting the ring 72 and the central through hole 70a at a predetermined angle, respectively. And a plurality of through holes 76 formed by the ring 72, the center through hole 70 a, and the connecting member 74 to pass water through the ring 72.

Next, the operation and effects of the magnetization hexagonal water production apparatus using the magnetizer according to the embodiment of the present invention configured as described above will be described.

First, for example, the nut 56b is screwed into the threaded portion 54b formed on one side (right side) of the elongated bolt 54, and then the other side (left) of the elongated bolt 54 is centered on the circular permanent magnet 50. It is inserted into the through-hole 50a formed in the hole, and is then inserted into the through-hole yoke 52b formed in the center of the spacer 52.

As such, the elongated bolts 54 are alternately disposed between the circular permanent magnets 50 and the spacers 52 in the through holes 50a and 52b formed at the centers of the circular permanent magnets 50 and the spacers 52. Then, after the spacer 52 is finally inserted, the circular permanent magnet 50 and the spacer 52 are firmly screwed together with the nut 56a to the threaded portion 54a formed on the left outer circumferential surface of the elongated bolt 54. ) Closely.

As described above, after the circular permanent magnet 50 and the spacer 52 are inserted into the elongated bolt 54, the nut (screw) is formed on the threaded portions 54a and 54b respectively formed on the left and right outer peripheral surfaces of the elongated bolt 54. After screwing together 56a and 56b, one side of the elongated bolt 54 is inserted into the cylindrical cylinder 60 made of stainless steel.

Next, the left and right ends of the elongated bolt 54 inserted into the cylindrical cylindrical body 60 are inserted into the central through hole 70a formed in the support bracket 70, and then the cylindrical member 60 When the threaded portions (not shown) formed on the inner circumferential surfaces of the left connecting member 64 and the right connecting member 65 are screwed to the threaded portions 62a and 62b formed on both outer peripheral surfaces of the left and right sides of the elongated bolt 54. Since the support bracket 70 supports the right end portions, the circular permanent magnet 50 and the circular spacer 52 are installed concentrically with a predetermined distance from the inner circumferential surface of the cylindrical body 60.

Then, the left connecting member 64 is screwed to the threaded portion 62a formed on the left outer peripheral surface of the cylindrical body 60, and the right connecting member 65 is formed on the right outer peripheral surface of the cylindrical body 60 ( 62b), the threaded portion 64b formed on the outer peripheral surface of the pipe 64a of the left connecting member 64 is connected to a water supply pipe (not shown), and the threaded portion 65b formed on the outer peripheral surface of the right connecting member 65. ) Is connected to a water discharge pipe (not shown), and when water is supplied through the pipe 64a of the left connecting member 64, the inner circumferential surface of the cylindrical body 60 and the cylindrical body through the left connecting member 64. N and N poles, S and S poles of the circular permanent magnet 50 alternately pass through the spacers 52 while passing between the outer circumferential surfaces of the circular permanent magnet 50 inserted into the 60. The magnetic field lines are coming out of the N pole Since the magnetic field forms a magnetic field, the mineral component and water molecules contained in the water are magnetized while passing through the magnetic field, and the water is a space between the inner peripheral surface of the cylindrical body 60 and the circular permanent magnet 50, that is, 12,000. A magnetic force line of 1 to 13,000 gauss passes through a space forming a magnetic field from the N pole to the S pole and changes to a constant molecular structure in which the cluster of irregular water molecules is reduced, thereby changing to a bath water having excellent cleaning effect.

In other words, passing through the space between the inner circumferential surface of the cylindrical body 60 and the circular permanent magnet 50 causes the water to increase the repulsive force of the magnetic force lines, thereby forming a mutually strong repulsive magnetic field between the N poles and the S poles. As the water passing through is passed in the vertical direction with respect to the repulsive magnetic field, it changes to a certain molecular structure in which the cluster of irregular water molecules becomes smaller, thereby changing to a bath water having excellent cleaning effect.

In addition, the magnetization hexagonal water production apparatus using the magnetizer according to the present invention is applied to the principle that the polarity of the water molecule structure is magnetized by passing the repulsive magnetic force between the N and N poles and the S and S poles at a right angle, N Since the spacer 52 made of iron plate was installed between the circular permanent magnets 50 in order to strengthen the repulsive magnetic field between the pole and the N pole and between the S pole and the S pole, the magnetization hexagonal number having a small molecular structure (cluster) was provided. Change to.

When using a magnetized hexagonal water with a small molecular structure (cluster) as a bath water, it improves the solubility of water-soluble gemstones containing minerals such as calcium carbonate stored in a filter medium tank (not shown), which is beneficial to the human body, Since dissolved calcium carbonate is dissolved in the bath water, beneficial minerals such as calcium act on the human body effectively, reducing the surface tension of the bath water, resulting in excellent cleaning effect and suppressing the growth of various bacteria. .

Therefore, the magnetization hexagonal water production apparatus using the magnetizer of the present invention by changing the surface tension of the water by the magnetic action of the molecular structure of the water can be useful to the various mineral components contained in the water useful to the human body, the magnetic strength is 12,000 gauss N-pole, N-pole, S-pole and S-pole are arranged at regular intervals facing each other through spacers using a permanent magnet of 13,000 gauss to increase magnetic field strength and magnetic flux density to pass water through the water. The surface tension can be changed to small magnetization hexagonal numbers.

In the above description, although illustrated and described with reference to specific embodiments, the present invention is not limited to this, for example, by those of ordinary skill in the art without departing from the concept of the present invention Of course, the design can be changed in various ways.

As described above, according to the apparatus for producing a magnetized hexagonal water using a magnetizer of the present invention, the surface tension of the water is changed by magnetic action of the molecular structure of the water, so that various mineral components contained in the water can act effectively on the human body. N-pole, N-pole, S-pole and S-pole are arranged at regular intervals facing each other through spacers using permanent magnets with a intensity of 12,000 gauss to 13,000 gauss, increasing magnetic field strength and magnetic flux density to pass water. It has the effect that the surface tension of the circulating water can be changed to a small magnetization hexagonal water.

Claims (3)

A circular permanent magnet 50 having a magnetic strength of 12,000 gauss to 13,000 gauss, a circular spacer 52 of a nonmagnetic material thinner than the permanent magnet 50, and the circular permanent magnet 50 and the circular spacer 52 Elongated bolts 54 for inserting the circular permanent magnets 50 and the circular spacers 52 alternately through the through holes 50a and 52b formed in the center, respectively, and generated in the circular permanent magnets 50. The circular permanent magnets 50 and the circular spacers 52 are alternately inserted into the elongated bolts 54 so that the water passing through the perpendicular direction is changed into the magnetization hexagonal number. A pair of nuts 56a and 56b respectively screwed into the threaded portions 54a and 54b formed on both sides of the elongated bolt 54 and the circular permanent magnet 50 inserted and supported by the elongated bolt 54, respectively. And receiving the circular spacer 52 Is formed with a cylindrical cylinder 60 made of stainless steel, and through holes 76 for supporting both ends of the elongated bolts 54 so as to be fixed concentrically in the cylindrical cylinder 60 and passing water therethrough. And a pair of support brackets 70 having a central through hole 70a formed at the center thereof, and the circular permanent magnets 50 and the circular spacers 52 and the elongated bolts alternately inserted into the elongated bolts 54, respectively. A pair of nuts 56a, 56b screwed into the threaded portions 54a, 54b formed at both ends of the 54, and the support bracket 70 for supporting the left and right sides of the pair of nuts 56a, 56b, respectively. The cylindrical body 60 made of stainless steel and the threaded portions 62a and 62b formed on the outer peripheral surfaces of both sides of the cylindrical body 60, respectively, are introduced into the inlet 64c through which water is introduced and the introduced water is discharged to the outside. It characterized in that the discharge port 65c is composed of left and right connecting members (64, 65) respectively formed Magnetized hexagonal water producing apparatus using an magnetization. According to claim 1, The left connecting member 64 is formed with a screw portion (64b) on the outer circumferential surface of the pipe (64a) extending to one side to be connected to the water supply pipe, the right connecting member 65, the water discharge pipe A magnetization hexagonal water production apparatus using a magnetizer, characterized in that a screw portion (65b) is formed on the outer circumferential surface of the pipe (65a) extending to one side so that it can be connected to. The support bracket 70 of claim 1, wherein the support bracket 70 supports a ring 72 having a central through hole 70a formed at a center thereof, and supports the ring 72 and the central through hole 70a at an angle. And a plurality of through holes 76 formed by the connecting member 74 to connect and the ring 72, the central through hole 70a, and the connecting member 74 to pass water. Magnetization hexagonal water production apparatus using a magnetizer.

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