JP2649904B2 - Method and apparatus for magnetizing water - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for magnetizing water which can efficiently apply magnetism to water in piping.

[0002]

2. Description of the Related Art The quality of tap water varies slightly depending on the water source. Recently, however, there is a problem in taste and smell as well as deterioration in the quality of water taken, and there is an urgent need for improvement. In addition, water forms a group of its molecules. It is said that tap water, which is said to be bad, has a large molecular group on average, and delicious natural water has a small molecular group. Water with a small water molecule population is considered to be delicious because the movement of water molecules is activated and activated. Also, in general,
Rust and scale often occur in water pipes and water storage tanks, and when rust and scale occur in pipes and water storage tanks, the pipe diameter is narrowed and the efficiency of flowing water deteriorates. May lead to damage. Therefore, a method has been adopted in which water is magnetized to activate water molecules, thereby making the water delicious, and dissolving and discharging rust and scale in the piping.

[0003]

However, in the conventional method, when magnetism is applied to water using a plurality of magnets, even if the magnets are arranged along the flow direction of water,
No research has been conducted on the magnet arrangement and combination method based on the intrinsic properties of magnets, and depending on the flow rate, flow velocity, strength of water pressure, and the type and content of substances contained in water, the lines of magnetic force can be fully exhibited in water. It cannot change the dynamics and equilibrium state of water molecules (clusters), does not work effectively under all water conditions, does not readily remove rust and scale in pipes, and water is difficult. It did not taste good and did not even benefit humans, plants, and the environment. The present invention has been made in order to solve such a conventional problem. In addition to differences in magnet material and magnetizing method, N, S,
N and S are arranged with different poles, and the adjacent magnets and the facing magnets are also all different poles. The distance between the opposite poles is 8 mm, and the distance between adjacent different poles is 18 mm. Accordingly, it is an object of the present invention to provide a method and apparatus for magnetizing water, which can efficiently magnetize water under all conditions.

[0004]

According to a first aspect of the present invention, there is provided a method of magnetizing water according to the present invention, wherein the N pole and the S pole are opposed to each other with a flow therebetween. Is installed in running water, the distance between the opposed magnets is formed smaller than the distance to other magnets installed in running water,
The water flowing between the opposed magnets is irradiated with magnetism at right angles to magnetize the water.

According to a second aspect of the present invention, there is provided a water magnetizing device, comprising: a storage portion having a pipe connection portion on both sides; and a plurality of magnet storage cases installed in the storage portion so as to face each other along the flow direction of the pipe. A permanent magnet fixed in the magnet storage case with the distance between the opposed magnets set to be smaller than the distance between the adjacent magnets, with the N pole and the S pole facing each other, and a water separator provided at the storage unit entrance. It is configured to have.

According to a third aspect of the present invention, in the water magnetizing apparatus according to the second aspect, the distance between the permanent magnets is 8 mm and the distance between the adjacent magnets is 18 mm.
It is installed and configured as.

[0007]

According to the method for magnetizing water according to claim 1 of the present invention,
Since a large number of magnets having N poles and S poles opposed to each other with the flow interposed are provided in the flowing water, the flowing water can be efficiently irradiated with magnetism at right angles. In addition, since the distance between the opposed magnets is formed smaller than the distance between the other magnets installed in the running water, the magnetism flows to the opposed magnets without being hindered by the magnetism of the other magnets, so that the magnets can be efficiently operated. The running water can be magnetized.

In the water magnetizing device according to the second aspect of the present invention, since the magnets are arranged in the storage section so as to face each other along the flow direction of the pipe, the flow of water in the storage section is not obstructed. The water flowing in the storage section can be efficiently irradiated with magnetism at right angles. And since the distance between the opposing magnets is set smaller than the distance between the adjacent magnets, the magnetism flows to the opposing magnet without being hindered by the magnetism of other magnets,
The water in the storage section can be efficiently magnetized. In addition, since the water separator is installed, the water spreads without stagnation in the storage portion, and the water can be uniformly magnetized.

According to the third aspect of the present invention, since the permanent magnets are set so that the distance between the opposing magnets is 8 mm and the distance between the adjacent magnets is 18 mm, a large number of magnets are regularly arranged in the storage section. And the magnetism can flow to the opposing magnet without being hindered by the magnetism of the magnets arranged adjacently, and the water in the storage portion can be efficiently magnetized.

[0010]

Next, embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a perspective view of an apparatus for magnetizing water according to one embodiment of the present invention, FIG. 2 is a perspective view of the magnetism generating unit, FIG. 3 is a partial cross-sectional view of the magnetism generating unit, and FIG. FIG. 5 is an exploded view of the magnet storage case (two-piece type), and FIG. 6 is an explanatory view showing an arrangement state of permanent magnets in the magnet storage case (four-piece type). 7 is an explanatory view showing an arrangement state of permanent magnets in the magnet storage case (two pieces), FIG. 8 is a front view of the same water separator, and FIG. 9 is a perspective view of the same water separator.

A magnetizing device 1 for water according to this embodiment is shown in FIGS.
As shown in FIG. 3, a rectangular storage portion 2 having a flange formed of a nonmagnetic steel material such as stainless steel, and a connection portion between the storage portion 2 and a water pipe, and a water pipe connection side flange 2a And an inlet-side connecting portion 3 having a housing portion connecting-side flange 2b, an outlet-side connecting portion 4 integrally formed at the housing portion outlet portion and having a water supply pipe connecting-side flange 3a, and a magnet housed inside the housing portion 2. The magnetism generating part 8 to which the storage case (four pieces type) 6 and the magnet storage case (two pieces type) 7 are connected, the water separator 9 provided at the inlet side connection part, and the magnet storage cases 6 and 7 It is composed of a permanent magnet 11 which is a built-in magnetic material.

The magnetism generating section 8 includes a magnet housing case (4).
The male part 12 and the female part 13 of the magnet storage case to be joined to the male part 12 and the magnet storage case (two pieces) 7 are connected in series along the flow of the pipe, and three of them are connected in series. Screw shaft 1
The magnet storage case (four-piece type) 6 and the magnet storage case (two-piece type) 7, which are vertically connected in eight stages by four, are connected to each other by eight in a vertical direction. . The screw shaft 14 is formed with a male screw as a whole, and the magnet housing case (four pieces) 6 includes a male part 12 and a female part 13.
The screw shaft 14 is inserted into the two holes 19 of the respective joints, and the magnet storage case (two-piece type) 7 has the male part 12 and the female part 1.
A screw shaft is inserted into one hole 21 formed in the magnet housing 3, and the start end and the end end of the screw shaft 14 are fastened and fixed by a nut 18 via a cylindrical spacer 17 between the magnet housing cases, respectively. Cases 6 and 7 are connected in the vertical direction.
Regarding the connection between the magnet storage case (four-piece type) 6 and the magnet storage case (two-piece type) 7, two holes formed in the male part 12 and the female part 13 of the magnet storage case (four-piece type) 6 are provided. 19
Of the magnet storage case, the connection fitting 16 is passed over the holes 21 formed in the male part 12 and the female part 13 of the magnet storage case (two-piece type) 7 and the nut together with the screw shaft 14. 18 fixed.

By the above steps, the magnet storage case (four-piece type) 6 and the magnet storage case (two-piece type) 7 are fixed while maintaining a predetermined width in the vertical, horizontal and width directions. Since the magnet storage cases are connected via the spacer 17, the facing distance T between the magnet storage cases is set to 8 mm.

As shown in FIG. 4, the magnet storage case (four-piece type) 6 has a magnet fixing outer frame 22, a cross partitioning frame 23 stored therein, a lid 24, and a The permanent magnet 11 is composed of a screw 26 fixed to the frame 22, and four permanent magnets 11 are fixed and housed between the magnet fixing outer frame 22, the partition frame 23 and the lid 24. The magnet fixing outer frame 22 has a vertical edge 27 having a magnet width (about 1 cm) on the side periphery of a square flat plate, and a screw screw hole 2 in the center of the flat plate.
8 are formed, and a projection 29 for forming the male portion 12 is provided at an upper portion, and a projection 30 for forming the female portion 13 is provided at a lower portion. Each of the projections has two holes 21 for inserting the screw shaft 14 therethrough. Is formed. The partition frame 23 is formed by bending a thin plate in a U-shape to cross each other, and
The character-shaped bending width H is formed at 18 mm, and a hole 31 for screw passing is provided at the intersection. The lid 24 has a hole 32 for screw insertion in the center of a square flat plate, a projection 29 forming the male portion 12 at the upper portion, and a projection portion 30 forming the female portion 13 at the lower portion. When the frame 22 and the lid 24 are joined by screws, the four permanent magnets 11 are fixed in the magnet storage case 6 and the projections 29 are
The male part 12 and the female part 13 are formed in the upper part and the lower part so that the protrusion parts 30 may overlap each other.

As shown in FIG. 5, the magnet storage case (two-piece type) 7 comprises a magnet fixed outer frame 35, a partition frame 36 housed therein, a lid 37, and the lid 37 and the magnet fixed outer frame. 35, two permanent magnets 11 are fixed to the magnet fixing outer frame 35 and the partitioning frame 36.
And is fixedly accommodated between the lid 37. The magnet fixing frame 35 has a magnet width (about 1 c
m), a screw screw hole 41 is formed in the center of the flat plate, and a protrusion 42 forming the male portion 12 and a protrusion 43 forming the female portion 13 are provided in the lower portion. A single screw shaft insertion hole 44 is formed in each of the protrusions 42 and 43. The partition frame 36 is formed by bending a thin plate into a U-shape, and the U-shaped bending width H is one.
It is formed to 8 mm, and a hole 46 for screw passing is provided at the intersection. The lid 37 has a hole 47 for screw insertion at the center of a rectangular flat plate, and a projection 42 forming the male portion 12 and a projection 43 forming the female portion 13 at the bottom are formed at the upper portion. When the cover 35 and the lid 37 are joined by the screw 38, the two permanent magnets 11 are fixed in the magnet storage case 7, and the projections 42 overlap each other and the projections 43 overlap each other, so that the male parts 12 And a female portion 13 are formed.

The permanent magnet 11 is 40 mm long and 40 m wide.
m, a rectangular parallelepiped with a width of 10 mm, one of the wide surfaces having an N pole and the opposite surface having an S pole are used. A magnet storage case (four pieces)
As shown in FIG. 6, the arrangement of the permanent magnets 11 housed in the permanent magnets 6 is such that the magnetic poles on the wide surface of the permanent magnets 11 are vertically and horizontally different from each other among the four permanent magnets. Have the same polarity. Also,
Permanent magnet 11 stored in magnet storage case (two pieces) 7
As shown in FIG. 7, when one of the magnetic poles on the wide surface of the permanent magnet 11 is the N pole, the other is the S pole, and has different polarities. Since the magnet housing cases are arranged to face each other, the wide surfaces of the permanent magnets housed therein also face each other, and when the magnetic pole of one of the wide surfaces of the facing magnet is the N pole, S The pole is configured such that the N pole is arranged when the magnetic pole on one wide surface of the facing magnet is the S pole.

The water separator 9 is fixed to the water inlet of the inlet side connecting portion 3, and as shown in FIGS. 8 and 9, a first dispersion plate 50 and a second dispersion plate 50 are provided. It is composed of a plate 51,
A large number of circular holes 53 are formed in each of the dispersion plates 50 and 51, and the circular holes 53 are formed so as to intersect with the flow of the piping.
A reinforcing plate 54 is sandwiched between the first dispersion plate 50 and the second dispersion plate 51. It should be noted that the actual capacity obtained by subtracting the components in the storage section 2 from the volume of the storage section 2 is set to be generally larger than the capacity of the water pipe having the same length.

Next, the operation of the apparatus for magnetizing water according to one embodiment of the present invention will be described. Since the permanent magnets 11 are arranged with the wide surfaces facing each other with respect to the flow of the pipe,
The smooth flow of water can be ensured without obstructing the flow of water in the storage section. The distance T between the opposed magnets is formed at 8 mm, and the distance H between the adjacent magnets is set at 18 mm. Therefore, the distance T between the opposed magnets becomes shorter than the distance H between the adjacent magnets, and the magnetism emitted from the permanent magnet 11 flows to the opposed magnet without being disturbed by the magnetism of the adjacent magnet, and the flowing water becomes perpendicular. Since it crosses, it is possible to effectively irradiate the water in the storage section with magnetism. Further, since the water separator 9 is provided, the water that has entered the storage unit 2 collides at a right angle with the water separator at the entrance, is dispersed and spreads throughout the rectangular storage unit 2, and stagnates. Without magnetizing water.
Further, since the two dispersion plates 50 and 51 of the water separator 9 are provided with circular holes intersecting with the flow of the pipe, the water that collides with the first dispersion plate 50 is further reduced by the second dispersion plate. Is dispersed by the dispersing plate 51, and the water is evenly dispersed throughout the storage unit 2. A reinforcing plate 54 is sandwiched between the first dispersing plate 50 and the second dispersing plate 51. Therefore, even if a large water pressure is applied, the dispersion plates 50 and 51 do not dent.

Since the wide surfaces of the adjacent magnets fixed to the magnet storage case have different polarities, the magnets emitted from the magnets do not repel the magnets of the adjacent magnets, and some magnets do not repel. Can also affect adjacent magnets, effectively irradiating the water in the storage unit with magnetism without wasting magnetic force.

The magnet storage case includes a magnet storage case (four-piece type) 6 and a magnet storage case (two-piece type) 7, so that when the volume of the storage part 2 is small, the magnet storage case (two-piece type).
7 can be installed, and magnet storage case (four-piece type) 6 and magnet storage case (two-piece type) 7 can be arbitrarily combined according to the size of the storage part, and the magnetism of water of appropriate size can be obtained. Device can be set.

Further, since the actual capacity obtained by subtracting the internal components of the storage section 2 from the volume of the storage section 2 is set to be generally larger than the capacity of the water pipe having the same length, the water passing through the water magnetizing device 1 is passed. The generated water can smoothly pass through the storage unit 2 without being subjected to resistance, so that magnetism can be efficiently applied to the water.

The embodiments of the present invention have been described above.
The specific configuration of the present invention is not limited to the present embodiment, and even if there is a design change or the like within a range not departing from the gist of the present invention, the present invention is included in the present invention. For example, the number of connected magnet storage cases can be arbitrarily set according to the size of the storage section. Further, in the present embodiment, the magnetic poles on the wide side of the permanent magnet have different vertical and horizontal magnetic poles among the four permanent magnets, and the permanent magnets located diagonally have the same polarity. However, it is possible to change the arrangement order of the polarities of the permanent magnets according to the water quality in the pipe, the flow velocity, and the like. And stainless steel was used as the material of the water magnetizer,
In addition, ceramics, synthetic resins, and the like can be used. Further, as shown in FIG. 10, it is also possible to set the magnet storage cases (four pieces) 6 in parallel depending on the size of the storage unit, and to set the size of the magnetic generation unit 8 arbitrarily. Can be.

[0023]

As described above, in the method for magnetizing water according to the first aspect of the present invention, the magnet having the N pole and the S pole opposed to each other is placed in a state of flowing water while sandwiching the flow. Since a large number are installed in the inside, magnetism can be efficiently applied to running water at right angles. In addition, since the distance between the opposed magnets is set smaller than the distance from the other magnets installed in the running water, the magnetism flows to the opposed magnets without being hindered by the magnetism of the other magnets, so that the magnets can be efficiently operated. The effect that the water in the pipe can be magnetized can be obtained.

Further, in the water magnetizing device according to the second aspect, since the magnets are arranged in the storage section so as to face each other along the flow direction of the pipe, the flow of water in the storage section is prevented. In addition, it is possible to efficiently irradiate water flowing in the storage section with magnetism at right angles. And since the distance between the opposing magnets is set smaller than the distance between the adjacent magnets, the magnetism flows to the opposing magnets without being hindered by the magnetism of other magnets, and the water in the storage unit is efficiently magnetized. can do.
In addition, since the water separator is provided, the water spreads without stagnation in the storage portion, and effects such as uniform magnetization of the water can be obtained.

In the apparatus for magnetizing water according to claim 3, since the magnets are installed with the distance between the opposed magnets being 8 mm and the distance between the adjacent magnets being 18 mm, a large number of magnets are regularly stored. At the same time, the magnetism is not obstructed by the magnetism of the magnets arranged adjacently, but flows to the magnets facing each other, so that the effect of efficiently magnetizing the water in the storage section is obtained.

[Brief description of the drawings]

FIG. 1 is a perspective view of a water magnetizing apparatus according to an embodiment of the present invention.

FIG. 2 is a perspective view of the magnetism generating unit.

FIG. 3 is a partial cross-sectional view of the magnetic generation unit.

FIG. 4 is an exploded view of the magnet storage case (four pieces).

FIG. 5 is an exploded view of the magnet storage case (two pieces).

FIG. 6 is an explanatory view showing an arrangement state of permanent magnets in the magnet storage case (four pieces).

FIG. 7 is an explanatory view showing an arrangement state of permanent magnets in the magnet storage case (two pieces).

FIG. 8 is a front view of the water separator.

FIG. 9 is a perspective view of the water separator.

FIG. 10 is a perspective view of a magnetism generating unit according to another embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Magnetization apparatus of water 2 Storage part 3 Inlet side connection part 4 Outlet side connection part 6 Magnet storage case (4 pieces type) 7 Magnet storage case (2 pieces type) 8 Magnetic generation part 9 Water separator 11 Permanent magnet 12 Male Part 13 Female part 14 Screw shaft 16 Connection fitting 17 Spacer 18 Nut 19 Hole 21 Hole 22 Magnet fixed outer frame 23 Partition frame 24 Cover 26 Screw 27 Standing edge 28 Screw screw hole 29 Projection 35 Magnet fixed outer frame 36 Partition frame 37 cover 38 screw 41 screw screw hole 42 projecting part 43 projecting part 46 hole 47 hole 50 dispersion plate 51 dispersion plate 53 circular hole T distance H distance

Claims (3)

(57) [Claims] 1. A large number of magnets having N poles and S poles opposed to each other with a flow interposed therebetween are installed in flowing water, and the distance between the opposed magnets is set to the distance from another magnet installed in flowing water. A method of magnetizing water, comprising forming the magnet to a smaller size and irradiating the water flowing between the opposed magnets with magnetism at right angles to magnetize the water. 2. A storage portion having a pipe connection portion on both sides, a plurality of magnet storage cases installed in the storage portion so as to face each other along a flow direction of the pipe, and an N pole and an S pole are opposed to each other. A permanent magnet fixed in the magnet storage case in which a distance between opposed magnets is set smaller than a distance between adjacent magnets, and a water separator provided at a storage unit entrance, wherein water is magnetized. apparatus. 3. The permanent magnet has a distance between opposing magnets of 8 m.
The water magnetizing device according to claim 2, wherein the distance between the adjacent magnets is 18 mm.