JP3946871B2 - Water magnetizer using a combination of magnets with different characteristics - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a water magnetizing apparatus capable of efficiently applying magnetism to water in a pipe.
[0002]
[Prior art]
The quality of tap water differs slightly depending on the water source, but recently there has been a problem in taste and odor along with the deterioration of the quality of water taken, and there is a need for improvement. In addition, water forms a group of molecules, and tap water, which is said to be poor, has a large molecular group on average, and delicious natural water is said to have a small group of molecules. Water with a small molecular group of water is considered to be delicious because the movement of water molecules is activated and activated. In general, rust and scale are often generated inside water pipes and water tanks. When rust and scale are generated in pipes and water tanks, the diameter of the pipe is narrowed and the efficiency of running water deteriorates. It may weaken the piping and cause damage to the water supply system. Therefore, a method is adopted in which water is magnetized to activate water molecules to make the water delicious and to dissolve and discharge rust and scale in the pipe.
[0003]
[Problems to be solved by the invention]
By the way, when the flow rate of water in the pipe is high, it passes through a weak magnetic field. When the flow rate of water is low, it passes through a strong magnetic field. It is known that water molecules are excited by this, and as a result, the water molecules become small and activated. However, in the past, since the magnetic force of the magnet arranged in the pipe was constant, it was possible to effectively magnetize water when the strength of the magnetic force matched the flow velocity of the water flowing in the pipe, but not so. There was a problem that water could not be magnetized effectively.
The present invention has been made to solve such a conventional problem, and the object of the present invention is to provide a pipe with a magnet having a strong magnetic force and a magnet having a weak magnetic force so as to be strong against water in the pipe. To provide a water magnetizing apparatus using a combination of magnets having different characteristics that can efficiently and stably magnetize water regardless of whether the flow velocity of water is high or low by irradiating different magnetic field lines is there.
[0004]
[Means for Solving the Problems]
As means for achieving the above object, in a water magnetizing apparatus using a combination of magnets having different characteristics according to the present invention (hereinafter referred to as “water magnetizing apparatus”), a storage section having pipe connecting sections on both sides; A large number of magnet housing cases installed in the housing portion so as to face each other along the flow direction of the pipe, and a permanent magnet fixed in the magnet housing case with the N and S poles facing each other. In an apparatus having a water separator provided at the entrance of the storage unit,
A part of the permanent magnet is made stronger than the magnetic force of the other permanent magnet, and the permanent magnet is installed such that the distance between the opposing magnets is shorter than the distance between adjacent magnets.
[0005]
In the water magnetizing apparatus of the present invention, the magnets are arranged in the storage portion so as to face each other along the flow direction of the pipe. Can be efficiently irradiated at right angles. Moreover, since the water divider is installed, the water spreads without any stagnation in the storage portion, and the water can be uniformly magnetized. In addition, since the magnetic force of a part of the magnet is made stronger than the other magnets, the magnetic force lines can always be efficiently applied to achieve magnetism regardless of the flow velocity.
[0006]
In addition, since the permanent magnet is installed so that the distance between the opposing magnets is shorter than the distance between the adjacent magnets, a large number of magnets can be regularly stored in the storage portion, and the magnetic lines of force are arranged adjacent to each other. It can flow between the opposing magnets without being disturbed by the magnetism of the magnets, and can efficiently magnetize the water in the storage unit.
[0007]
[Embodiment]
Next, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
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 sectional view of the magnetism generating unit, and FIG. -Exploded view of the case (four pieces), FIG. 5 is an exploded view of the magnet housing case (two pieces), and FIG. 6 is an arrangement state of the permanent magnets in the magnet housing case (four pieces). FIG. 7 is an explanatory view showing the arrangement of the permanent magnets in the magnet storage case (two-piece type), FIG. 8 is a front view of the water divider, and FIG. 9 is the water divider. It is a perspective view.
[0008]
As shown in FIGS. 1 to 3, the water magnetizing apparatus 1 according to this embodiment includes a rectangular storage unit 2 having a flange formed of a non-magnetic steel material such as stainless steel, and a water supply for the storage unit 2. It is a connection part with piping, Comprising: The inlet side connection part 3 which has the water pipe connection side flange 2a and the accommodating part connection side flange 2b, and the exit which is integrally formed in the accommodating part outlet part, and has the water pipe connection side flange 3a Side connecting portion 4, magnet housing case (four pieces) 6 and magnet housing case (two pieces) 7 housed in housing portion 2, and magnetism generating portion 8 connected to inlet housing, inlet side connection It consists of a water separator 9 provided in the section and a permanent magnet 11 which is a magnetic body built in the magnet housing cases 6 and 7.
[0009]
The magnetism generating unit 8 includes a magnet housing case (4 pieces) 6 and a magnet housing case (2 pieces) 7 which are joined to the male portion 12 and the male portion 12 along the flow of the pipe. Three female portions 13 joined together and connected in series are connected vertically by a screw shaft 14 in eight stages, and a magnet storage case (four pieces) 6 and a magnet connected in eight stages vertically. A storage case (two-piece type) 7 is configured to be connected horizontally by a connecting metal fitting 16. The screw shaft 14 is formed with a male screw as a whole, and in the magnet housing case (four pieces) 6, the screw shaft 14 is inserted into the two holes 19 at the joint portions of the male portion 12 and the female portion 13. The magnet housing case (two-piece type) 7 has a screw shaft inserted into one hole 21 formed in the male portion 12 and the female portion 13, and a cylindrical space between the magnet housing cases. The start end portion and the end end portion of the screw shaft 14 are fastened and fixed by the nut 18 via the spacer 17, and the magnet housing cases 6 and 7 are connected in the axial direction. The connection between the magnet housing case (four pieces) 6 and the magnet housing case (two pieces) 7 is formed in the male portion 12 and the female portion 13 of the magnet housing case (four pieces) 6. Of the two holes 19 formed, the respective holes on the connecting side of the magnet housing case and the holes 21 formed in the male portion 12 and the female portion 13 of the magnet housing case (two-piece type) 7 are provided. The connecting bracket 16 is spanned and fixed together with the screw shaft 14 by the nut 18.
[0010]
According to the above-described process, the magnet housing case (four pieces) 6 and the magnet housing case (two pieces) 7 are fixed in a state of maintaining predetermined widths in the vertical, horizontal and width directions. Since the magnet housing cases are connected via a spacer 17, the facing distance T between the magnet housing cases is set to 8 mm.
[0011]
As shown in FIG. 4, the magnet housing case (four pieces) 6 includes a magnet fixing outer frame 22, a cross partition frame 23 housed therein, a lid 24, and the lid 24. The permanent magnet 11 is composed of screws 26 fixed to the magnet fixing outer frame 22, and four permanent magnets 11 are fixed and stored between the magnet fixing outer frame 22, the partition frame 23 and the lid 24. The magnet fixing outer frame 22 has a standing edge 27 having a magnet width (1 cm) on the side periphery of a square flat plate, a screw screw hole 28 is formed at the center of the flat plate, and a protrusion that forms the male portion 12 at the top. The protrusion 29 which forms the female part 13 in the part 29 and the lower part is provided, and the hole 21 for screw-screw 14 insertion is formed in two places in each protrusion. The partition frame 23 is formed by bending a thin plate-like object into a U shape and intersecting with a cross, and the U-shaped bent width H is formed to be 18 mm. 31 is provided. The lid 24 has a screw insertion hole 32 at the center of a square flat plate, a protrusion 29 that forms the male part 12 at the top, and a protrusion 30 that forms the female part 13 at the bottom. When the frame 22 and the lid 24 are joined by screws, the four permanent magnets 11 are fixed in the magnet housing case 6, and the protruding portions 29 and the protruding portions 30 are overlapped so that the upper portion and the lower portion are overlapped. The male part 12 and the female part 13 are formed.
[0012]
As shown in FIG. 5, the magnet housing case (two-piece type) 7 has a magnet fixing outer frame 35, a partition frame 36 housed therein, a lid 37, and a magnet for fixing the lid 37 to a magnet. The permanent magnet 11 is composed of a screw 38 fixed to the outer frame 35, and the two permanent magnets 11 are fixed and accommodated between the magnet fixing outer frame 35, the partition frame 36 and the lid 37. The magnet fixing frame 35 has a standing edge 39 having a magnet width (about 1 cm) on the side periphery of a rectangular flat plate, a screw screw hole 41 is formed at the center of the flat plate, and a protrusion that forms the male portion 12 at the top. The protrusion 42 which forms the female part 13 in the part 42 and the lower part is provided, and one hole 44 for screw insertion is formed in each protrusion 42,43. The partition frame 36 is obtained by folding a thin plate-like object into a U shape, the U-shaped folding width H is formed to 18 mm, and a screw insertion hole 46 is provided at the intersection. Yes. The lid 37 has a hole 47 for screw insertion at the center of a rectangular flat plate, a protrusion 42 that forms the male part 12 at the upper part, and a protrusion 43 that forms the female part 13 at the lower part. When the frame 35 and the lid 37 are joined by the screw 38, the two permanent magnets 11 are fixed in the magnet housing case 7, and the protrusions 42 and the protrusions 43 are overlapped with each other at the upper part and the lower part. A male part 12 and a female part 13 are formed.
[0013]
The permanent magnet 11 is a rectangular parallelepiped having a length of 40 mm, a width of 40 mm, and a width of 10 mm. One of the wide surfaces is an N pole and the opposite surface is an S pole. As shown in FIG. 6, the arrangement of the permanent magnets 11 is such that the wide magnetic poles of the permanent magnets 11 have different vertical and horizontal magnetic poles among the four permanent magnets, and the permanent magnets 11 are located obliquely. Magnets have the same polarity. Further, as shown in FIG. 7, the arrangement state of the permanent magnets 11 accommodated in the magnet housing case (two-piece type) 7 is as follows. As shown in FIG. The poles are of different polarity. Since the magnet housing cases are arranged to face each other, the wide surfaces of the permanent magnets housed inside also face each other, and when the magnetic pole of one wide surface of the facing magnet is an N pole Is configured such that the N pole is disposed when the magnetic pole of one wide surface of the opposing magnet is the S pole. Then, the magnets in the first row and the third row of the magnet housing case (four pieces) 6 and the magnet housing case (two pieces) 7 connected in series along the pipe flow. The permanent magnets 11 housed in the housing case (four pieces) 6 and the magnet housing case (two pieces) 7 are formed of ferrite magnets (about 1600 gauss) having a weak magnetic force, and the second row magnets. The permanent magnet 11 housed in the housing case (four pieces) 6 and the magnet housing case (two pieces) 7 is formed of a rare earth magnet (about 4800-6400 gauss) having a strong magnetic force, and the flow rate of water. Is fast (more than 2 meters per second), the magnetic lines of force of the first and third magnets with weak magnetic force act to activate water molecules, and the flow rate of water is slow (less than 2 meters per second) ) Can activate water molecules by the action of the magnetic field lines of the second row of magnets with strong magnetic force, and is always stable regardless of the flow rate. It is possible to magnetized water Te.
[0014]
The water divider 9 is fixed to the water inlet of the inlet side connecting portion 3, and as shown in FIGS. 8 and 9, from the first dispersion plate 50 and the second dispersion plate 51. Each of the dispersion plates 50 and 51 is formed with a large number of circular holes 53, and the circular holes 53 are formed so as to intersect with the flow of the pipe, and the first dispersion plate 50 and the second dispersion plate are formed. A reinforcing plate 54 is sandwiched between 51. In addition, the substantial capacity | capacitance which deducted the components in the storage part 2 from the capacity | capacitance of the storage part 2 is set so that it may become larger than the water arrangement | positioning capacity of the same length normally.
[0015]
Next, the operation of the water magnetizer according to one embodiment of the present invention will be described. Since the permanent magnet 11 is arranged with the wide surfaces facing each other with respect to the flow of the pipe, the smooth flow of water can be secured without hindering the flow of water in the storage unit, The distance T between the magnets is 8 mm, and the distance H between the adjacent magnets is 18 mm. Therefore, the distance T between the opposing magnets is closer than the distance H between the adjacent magnets, and the permanent magnet 11 emits the distance T. The generated magnetism flows to the facing magnet without being disturbed by the magnetism of the adjacent magnet and crosses the flowing water at a right angle, so that it is possible to effectively irradiate the water in the storage portion with magnetism. Further, since the water divider 9 is provided, the water that has entered the storage unit 2 collides with the water diverter at a right angle at the entrance, is dispersed and spreads throughout the rectangular storage unit 2, and itchy. Water can be magnetized. In addition, since the two dispersion plates 50 and 51 of the water separator 9 are provided so that the circular holes intersect with the flow of the pipe, the water that collides with the first dispersion plate 50 is the second one. The dispersion plate 51 disperses the water uniformly in the entire storage unit 2. Since the reinforcing plate 54 is sandwiched between the first dispersion plate 50 and the second dispersion plate 51, the dispersion plates 50 and 51 may be recessed even if a large water pressure is applied. Never do.
[0016]
And since the polarities of the wide surfaces of the adjacent magnets fixed to the magnet housing case are different polarities, the magnetic field lines emitted from the magnets do not repel the magnetic field lines of the adjacent magnets, and some of the magnetic field lines are The magnetic force lines can be effectively irradiated to the water in the storage unit without affecting the adjacent magnets and wasting the magnetic field lines.
[0017]
Since the magnet housing case includes a magnet housing case (four pieces) 6 and a magnet housing case (two pieces) 7, when the volume of the housing portion 2 is small, the magnet housing case ( It can be installed by using a two-piece type) 7, and the magnet storage case (four-piece type) 6 and the magnet storage case (two-piece type) 7 can be arbitrarily combined depending on the size of the storage unit. An appropriately sized water magnetizer can be installed.
[0018]
Moreover, since the substantial capacity | capacitance which deducted the part in the storage part 2 from the volume of the storage part 2 is installed so that it may become larger than the water pipe capacity of the same length normally, the water which passes the water magnetizer 1 The container 2 can pass smoothly without receiving resistance, and can effectively cause magnetism to act on water.
[0019]
Further, among the magnet housing case (four pieces) 6 and the magnet housing case (two pieces) 7 connected in series along the flow of the pipe, the first row and third row magnets. The permanent magnets 11 housed in the housing case (four pieces) 6 and the magnet housing case (two pieces) 7 are formed of ferrite magnets having a weak magnetic force and the second row of magnet housing cases ( The permanent magnets 11 housed in the four-piece type 6 and the magnet-housing case (two-piece type) 7 are formed of rare earth magnets with a strong magnetic force, so when the flow rate of water is high (more than 2 meters per second) ) Activates water molecules by the magnetic lines of the first and third magnets with weak magnetic force, and when the water flow rate is slow (less than 2 meters per second), the second magnet with strong magnetic force The magnetic lines of force act to activate water molecules, and water can always be efficiently magnetized regardless of the flow rate.
[0020]
The embodiment of the present invention has been described above, but the specific configuration of the present invention is not limited to the present embodiment, and the present invention can be applied even if there is a design change or the like without departing from the gist of the invention. included. For example, in the above-described embodiment, the first row of the magnet storage case (four pieces) 6 and the magnet storage case (two pieces) 7 connected in series along the flow of the pipe, The permanent magnets 11 housed in the third row magnet housing case (four pieces) 6 and the magnet housing case (two pieces) 7 are formed of ferrite magnets having a weak magnetic force, and the second row magnets. The permanent magnets 11 housed in the housing case (four pieces) 6 and the magnet housing case (two pieces) 7 are formed of strong rare earth magnets. Alternatively, only the third row may be changed. Further, one of the magnet housing case (four pieces) 6 and the magnet housing case (two pieces) 7 is formed of a ferrite magnet having a weak magnetic force, and the other is formed of a rare earth magnet having a strong magnetic force. Alternatively, a part of the permanent magnet housed in the magnet housing case (four pieces type) 6 or the magnet housing case (two pieces type) 7 is formed of a ferrite magnet having a low magnetic force or a rare earth magnet having a strong magnetic force. May be. In the above embodiment, the distance T between the opposing magnets is set to 8 mm and the distance H between the adjacent magnets is set to 18 mm. However, a magnet having a strong magnetic force takes a distance T between the opposing magnets larger than 8 mm. By making the distance H between adjacent magnets larger than 18 mm accordingly, the number of magnets installed can be reduced and the cost can be reduced. Also in this case, the distance between the opposing magnets is made smaller than the distance between adjacent magnets. Further, the number of magnet housing cases connected can be arbitrarily set according to the size of the housing portion. Further, in this embodiment, the magnetic poles on the wide surface of the permanent magnets are different in the vertical and horizontal magnetic poles among the four permanent magnets, and the permanent magnets located obliquely 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. In addition, stainless steel is used as the material for the water magnetizer, but ceramics, synthetic resins, and the like can also be used. Further, as shown in FIG. 10, it is possible to set the magnet housing case (four pieces) 6 in parallel according to the size of the housing portion, and the size of the magnetism generating portion 8 is arbitrarily set. can do.
[0021]
【The invention's effect】
As described above, in the water magnetizing apparatus of the present invention, since the magnets are arranged opposite to each other along the flow direction of the pipe in the storage unit, the water flow in the storage unit is obstructed. In addition, it is possible to efficiently irradiate the water flowing in the storage portion with magnetism at right angles. Moreover, since the water divider is installed, the water spreads in the storage unit without stagnation, and the effect that the water can be magnetized uniformly is obtained. In addition, by making a part of the magnet stronger than the magnetic force of other magnets, the magnetic field lines with different strengths are irradiated to the water. When water molecules are activated and the flow rate of water is slow, strong magnetic lines of force act to activate the water molecules, and regardless of the flow rate of water, the magnetic lines of force always act efficiently and magnetize the water. Can be achieved.
In addition, since the magnets are installed such that the distance between the opposing magnets is shorter than the distance between the adjacent magnets, a large number of magnets can be stored regularly, and the magnetism is the magnetism of the magnets arranged adjacent to each other. It is possible to flow between the opposing magnets without being obstructed and to effectively magnetize the water in the storage unit.
[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 generator.
FIG. 3 is a partial cross-sectional view of the magnetism generator.
FIG. 4 is an exploded view of the same magnet storage case (four pieces).
FIG. 5 is an exploded view of the magnet storage case (two-piece type).
FIG. 6 is an explanatory view showing an arrangement state of permanent magnets of the same magnet storage case (4 pieces type).
FIG. 7 is an explanatory view showing an arrangement state of permanent magnets of the magnet housing case (two pieces type).
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 generator according to another embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Water magnetizer 2 Storage part 3 Inlet side connection part 4 Outlet connection part 6 Magnet storage case (4 pieces type)
7 Magnet storage case (2 pieces)
8 Magnetic generating part 9 Water diverter 11 Permanent magnet 12 Male part 13 Female part 14 Screw shaft 16 Connecting bracket 17 Spacer 18 Nut 19 Hole 21 Hole 22 Magnet fixed outer frame 23 Partition frame 24 Lid 26 Screw 27 Vertical edge Part 28 Screw screw hole 29 Projection part 35 Magnet fixing outer frame 36 Partition frame 37 Lid 38 Screw 41 Screw screw hole 42 Projection part 43 Projection part 46 Hole 47 Hole 50 Dispersion plate 51 Dispersion plate 53 Circular hole T Distance H distance

Claims (1)

A storage portion having pipe connecting portions on both sides, a number of magnet storage cases installed in the storage portion so as to face each other along the flow direction of the pipe, and the magnet storage case with the N and S poles facing each other. -In a device having a permanent magnet fixed in the storage and a water separator provided at the entrance of the storage unit,
Different characteristics characterized in that a part of the permanent magnet is made stronger than the magnetic force of another permanent magnet, and the permanent magnet is installed such that the distance between opposing magnets is shorter than the distance between adjacent magnets. A water magnetizer using a combination of magnets.

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