KR200334221Y1 - Magnetized hexagonal water production and descaling device - Google Patents

Abstract

The present invention relates to a magnetized hexagonal water production and descaling apparatus, the upper portion that is coupled to face up and down in the conventional magnetized hexagonal water production and scale removal apparatus to magnetize the fluid passing through the magnetic field of the magnetic body by incorporating a magnetic body in the housing The neodymium magnets with strong magnetic force are installed on both sides of the pipe and facing each other so that the same poles face each other so that the magnetic lines with double magnetic flux density are effectively applied to the fluid flowing inside the pipe. It is intended to increase the magnetization efficiency.

Description

Magnetized hexagonal water production and descaling device

The present invention relates to a magnetization hexagonal water production and descaling apparatus, and more specifically, by installing the two poles of the neodymium magnet adjacent to the outer side of the pipe to which the drinking water is supplied utilizing the characteristics of the magnetic ion The present invention relates to a magnetization hexagonal water production and descaling apparatus capable of doubling the effect of magnetization treatment, as well as simplifying the structure of the magnetization treatment apparatus.

As is already known, the molecular structure of water is formed by combining one oxygen (O) atom of -ion and two hydrogen (H) atoms of + ion with each other. In the solid and gaseous state, the volume increases.

It is well known that juices of animals and plants, including humans, have hexagonal molecular structures, not normal water structures, even at room temperature.

However, in the hexagonal structured magnetized water, no bacteria can absorb oxygen in the water molecule, and six times more hydrogen atoms of + ions and -ions of oxygen are inevitably retained in the process of bonding with each other. There are various sanctions by about 0.5 gauss of magnetic energy, which makes it difficult for the bacteria to survive.

Therefore, the more magnetized water in our human body, the better. Indirectly, the body fluid in our body detoxifies and neutralizes various toxins and prevents the growth of germs.

However, today's modern people, indirectly or indirectly of low quality air and heavy metals caused by various environmental pollution such as nicotine by smoking, harmful toxin intake such as caffeine, alcohol, preservatives and antibiotics, and medicine, water quality and air Since it is injected into the human body through a conventional route, only a certain amount of white blood cells and structured body fluids are incapable of dealing with it, and it has been shown to suffer from various adult diseases such as hypertension, neuralgia, and diabetes.

In addition, because of the distrust of tap water, they usually boil and drink, but in this case, various residual germs and toxicities are neutralized to some extent, but instead, the oxygen itself is lacking, which may cause inferior resistance.

Therefore, researchers in developed countries have studied and analyzed the structure of the drink and how it changes in the human body. It is already known that by lowering and using magnetism it is easy to obtain magnetized water.

1 is a perspective view showing a conventional magnetization hexagonal water production apparatus, as shown in Figure 1, through the upper housing 10 through which the through-circuit wall 11 through which the pipe 30 to which the drinking water is supplied is passed through Opening portions 12 are formed at the intermediate portions on both sides of the circumferential wall 11, and the ferrous metal plate 14 is embedded inside the opening portions 12.

A pipe is formed so that the pipe 30 through which the drinking water is supplied is also formed in the center of the lower housing 20 in which the U-shaped groove is formed inside the cube and the permanent magnet 25 is formed therein. A through circumferential wall 21 having a radius of 30 is formed so that the upper housing 10 and the lower housing 20 are bolted to face each other.

Figure 2 is a schematic diagram showing the amount of magnetic force by the general permanent magnet of the conventional magnetized hexagonal water production apparatus, the magnetic field of the magnetic pole of the N pole is formed in the N pole, one end of the permanent magnet 25, and the S pole in the S pole, the other end The magnetic field of the magnetic force of the magnetic field 28 is formed in the form of concentric circles around each pole.

Therefore, the magnetic force line between the N pole and the S pole is induced only in a very small portion, so that the magnetic force on the water flowing inside the pipe 30 is weak, and the magnetization efficiency is very low.

In addition, in order to increase the magnetization performance by placing the magnetic metal plate 14 without the magnet on the upper side of the permanent magnet 25 to increase the magnetization efficiency by increasing the supply range of the magnetic force, but the permanent conveyed through the iron metal plate 14 The magnet's weak magnetic force did not increase the magnetizing efficiency.

The devised hex hexagonal water production and descaling device has been devised to solve the above problems of the prior art, and has a neodymium magnet having a strong magnetic force inside the upper and lower housings which are coupled up and down. The purpose of the present invention is to provide a magnetization hexagonal water production and scale removal device which is installed so that the same poles face each other so that the magnetic force lines of which the magnetic flux density is doubled effectively act on the fluid flowing between the N pole and the S pole to increase the magnetization efficiency. It is done.

1 is a perspective view showing a conventional magnetization hexagonal water production apparatus,

Figure 2 is a schematic diagram showing the amount of magnetic force by the general permanent magnet of the conventional magnetization hexagonal water production apparatus,

3 is a perspective view of the magnetization hexagonal water production apparatus according to the present invention,

4 is a cross-sectional view taken along the line A-A of FIG.

Figure 5 is a perspective view schematically showing another embodiment of the magnetization hexagonal water production apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

30: pipe, 40: upper housing,

41,51: pipe groove, 42,52: stepped portion,

48: fastening means, 49: screw hole,

60: long groove, 65: corrosion inhibitor,

70: neodium

Magnetized water production apparatus according to the present invention is a conventional magnetized hexagonal water production and scale removal device to magnetize the fluid passing through the magnetic field of the magnetic material by incorporating a magnetic material in the housing, a plurality of screw holes are drilled on the four sides of the border and the center of the bottom The upper housing of the non-magnetic hexahedron having a semicircular cross section is provided in the longitudinal direction to protrude the upper half of the pipe, and has a stepped portion having a predetermined thickness at the center of the pipe groove, and the screw hole on the four sides of the pipe. The lower groove of the non-magnetic hexahedron coupled with the lower surface of the upper housing and the pipe groove and the stepped portion are concave in shape so that the screw groove is formed and the center of the upper surface is symmetrical with the pipe groove, and the stepped portion of the pipe groove At least two grooves formed on both side walls in parallel with the pipe grooves, respectively. As the above-mentioned long groove, neodium each inserted and fixed so that the same poles are opposed to the inside of the long groove, a corrosion inhibitor filled in the inside of the long groove into which the neodium is inserted and fastened, and fastening means for fastening the upper and lower housings. It is characterized in that the configuration.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the magnetized hexagonal water production and scale removal apparatus according to the present invention will be described in more detail.

Figure 3 is a perspective view of the magnetization hexagonal water production apparatus according to the present invention, Figure 4 is a cross-sectional view of the AA line of Figure 3, as shown in Figures 3 and 4, the pipe 30 of the circular pipe shape is supplied with drinking water is The drinking water flowing through the center of the apparatus and flowing into the pipe 30 is magnetized in the apparatus according to the present invention.

The present invention magnetization hexagonal water production and scale removal device is composed of the upper housing 40 and the lower housing 50 of the hexahedral shape.

The upper housing 40 has a pipe groove 41 indented to receive a half of the pipe 30 on its bottom surface, and an inner circumferential surface of the pipe groove 41 on the central portion of the pipe groove 41. Accordingly, the stepped portion 42 protruding by a predetermined height is protruded.

The inner circumferential surface of the stepped portion 42 is in surface contact with the outer circumferential surface of the pipe 30 to support the upper half of the pipe 30.

The lower housing 50 is coupled to the lower side of the upper housing 40 so as to face the upper housing 40 along the longitudinal direction in which the pipe 30 is installed in the center of the upper surface of the lower housing 50 having a hexahedron shape. When the pipe groove 51 having a semi-circular cross section symmetrical with the pipe groove 41 formed in the 40 is recessed and the upper housing 40 and the lower housing 50 are vertically coupled, the pipe groove 41 and the pipe The groove 51 forms a cylindrical passage up and down.

Meanwhile, the stepped portion 52 protrudes from the central portion of the pipe groove 51 so as to be symmetrical with the stepped portion 42 of the upper housing 40.

Long side grooves 60 are formed in both side walls of the stepped portion 52 in the transverse direction while forming a space from the upper end to the lower side by a predetermined depth.

Inside the long groove 60, a rectangular rectangular parallelepiped neodymium (NEODYMIUM) magnet 70 is filled with a corrosion inhibitor 65 such as silicon, for example.

The neodymium magnet 70 is a rectangular rectangular parallelepiped, the polarity of which is divided into an N pole on one side and an S pole on the other side of the rectangular parallelepiped along the longitudinal direction.

As shown in FIG. 4, when the neodium magnet 70 is installed in the left and right long grooves 60 around the center pipe 30, the polarity of the neodium magnet 70 is the pipe 30. The opposite poles should be installed facing each other.

Looking at the operation of the present invention made of such a configuration as the state facing each other of the same poles (N pole N pole, S pole S poles) of the neodium magnet 70 installed opposite to the left and right around the pipe 30, respectively. As the magnetic flux density is doubled due to the magnetic force of the counterpart generated at the pole of the magnetic pole, a magnetic force line (indicated by an arrow in FIG. 4) flows in a direction perpendicular to the advancing direction of the water flowing into the pipe 30.

When water is supplied to the inside of the pipe 30 and passes through the magnetization hexagonal water production and descaling apparatus according to the present invention, magnetism penetrates into the water by a magnetic force line of the neodium magnet 70 installed therein. Rapid magnetization is achieved.

5 is a perspective view schematically showing another embodiment of the magnetization hexagonal water production apparatus according to the present invention, the neodium in the long groove 60 of the stepped portion 52 protruding in the pipe groove 51 of the lower housing 50 The magnet 70 'is installed to face each other in the longitudinal direction, but the N pole is installed upward and the S pole is installed downward.

The pipe 30 is installed between the neodymium magnets 70 '.

The magnetization hexagonal water production and descaling device having such a configuration has the same poles (N pole N pole, S pole S pole) facing each other on the upper side and the lower side of the neodymium magnet 70 'installed on both sides, respectively. The magnetic flux density is doubled due to the magnetic force of the counterpart generated at the opposite poles, thereby forming a strong magnetic field in the pipe 30 (the arrow shown in FIG. 5 represents the magnetic field of force), and the neodymium magnets respectively built on both sides ( A strong magnetic force line is induced between the upper N pole of the 70 ') and the lower S pole to inject strong magnetic force into the water supplied into the pipe 30, thereby exhibiting excellent magnetization performance.

As described above, the magnetization hexagonal water production and descaling apparatus according to the present invention is installed so that the neodymium magnets face each other to face the same poles so that the magnetic flux density is doubled so that the strong magnetic lines act on the fluid flowing in the pipe. It is a useful design to increase the magnetization efficiency.

Claims (1)

In a conventional magnetized hexagonal water production and descaling apparatus for injecting a magnetic body in the housing to magnetize the fluid passing through the magnetic field of the magnetic body, A plurality of threaded holes 49 are drilled on the four sides of the four sides, and a pipe groove 41 having a semicircular cross section is recessed in the longitudinal direction so that an upper half of the pipe 30 is accommodated in the center of the bottom surface thereof. The upper housing 40 of the non-magnetic hexahedron with a stepped portion 42 having a predetermined thickness in the center of the, The pipe groove 51 and the stepped portion 52 are recessed in a shape in which a screw groove 59 is formed in the four-sided edge so as to correspond to the screw hole 49 and the upper surface center thereof is symmetrical with the pipe groove 41. A lower housing 50 of a nonmagnetic hexahedron coupled to the lower housing of the upper housing 40 while being interviewed; At least two or more long grooves 60 each having grooves formed in parallel to the pipe groove 51 on both side walls of the stepped portion 52 of the pipe groove 51, The neodymium magnet 70 is inserted and fixed so that the same pole is opposed to the inside of the long groove (60), Corrosion inhibitor 65 is filled in the inner groove 60 is inserted into the neodium magnet 70 is fixed, respectively; Magnetizing hexagonal water production and scale removal device, characterized in that consisting of a fastening means (48) for fastening the upper housing (40) and the lower housing (50).