JP3020039U - Magnetic reformer for water-containing liquid or liquid fuel - Google Patents

Abstract

(57) [Abstract] [Purpose] To provide an apparatus for activating (reforming) a liquid or liquid fuel containing water by using a magnetic field. [Structure] Cylindrical magnets having four or more magnetic poles in a cross section are arranged and held in a double manner inside and outside, and the magnetic poles of corresponding portions of the inside and outside cylinders are reversed. A water-containing liquid or liquid fuel is passed between these cylindrical magnets for magnetic modification. A spacer made of a non-magnetic material having a double cylindrical body and a partition wall extending in the axial direction of the cylindrical body,
It is interposed between the inner and outer cylindrical magnets. A cylindrical body made of a magnetic material is inserted into the inner cylindrical magnet to form a magnetic core.
The outer cylindrical magnet is inserted into the cylindrical body made of a magnetic material for magnetic shielding. The magnetic field strength between the cylindrical magnets is preferably 500
It is set to 0 to 10,000 G.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a magnetic reformer for water-containing liquids or liquid fuels, and more particularly to water-containing liquids such as drinking water, favorite beverages, fruit juices, alcoholic beverages, medical water, agricultural and livestock industry water, and precision industrial water. The present invention relates to a device for magnetically modifying or activating liquid fuel such as heavy oil, petroleum, kerosene, and gasoline.

[0002]

[Prior art]

 In recent years, as health consciousness has increased, various types of products aimed at promoting health have been developed and sold. Drinking tap water purification equipment is one such product. However, it has been pointed out that the filter-type water purification device becomes unsanitary when the filter is clogged.

In view of such social demands, the present inventor, as an engineer engaged in the application of magnetism, earnestly studied and studied whether or not the magnetic action on water-related substances could be applied, and the It was discovered that it has an unexpected effect not only on water-containing liquids but also on liquid fuels, and that such a magnetic action is remarkably exhibited in a specific mode of magnetic field application or magnetic strength. It is a thing.

[0004]

[Means for Solving the Problems]

 What is provided by the present invention is that a cylindrical magnet having four or more magnetic poles in the cross section is doubled inside and outside, and the magnetic poles of the corresponding portions of the inside and outside cylinders are reversed. And a magnetic reformer for water-containing liquid or liquid fuel, characterized in that the water-containing liquid or liquid fuel is magnetically reformed by passing between these cylindrical magnets. is there.

The following can be mentioned as preferred embodiments. (1) A spacer made of a non-magnetic material having a double cylindrical body and a partition wall between the double cylindrical body is interposed between the inner and outer cylindrical magnets, and the water-containing liquid or liquid fuel is interposed between the double cylindrical magnets. Form and maintain a flowing gap. (2) A cylindrical body made of a magnetic material is inserted into the inner cylindrical magnet to form a magnetic core.

(3) A magnetic circuit is formed by inserting the outer cylindrical magnet into a cylindrical body made of a magnetic material. This allows magnetic shielding. (4) The magnetic field strength between the double cylindrical magnets is set in the range of 5000 to 10,000 G, and more preferably 7000 to 10,000 G. (5) The number of magnetic poles in the cross section between the double cylindrical magnets is 6 or 8.

(6) At least one end in the axial direction of the inner cylindrical magnet is capped, and the cap has a shape in which the central portion of the axial line of the cylindrical body is the apex and decreases toward the circumferential portion of the inner cylindrical magnet. And acts so as to guide the flow of the water-containing liquid and the liquid fuel toward the one end side of the cylindrical magnet into the gap between the double cylindrical magnets. (7) In particular, a magnetic reformer for water or alcoholic beverages.

According to the present invention, the spacer of (1) and one cap having the shape of (6) are integrally formed, and the cap of the shape of (6) is formed at the other end of the spacer. There is also provided a member for a magnetic reformer of a water-containing liquid and a liquid fuel, which is characterized in that it is attached, and an inner cylindrical magnet and a core can be inserted inside the inner cylindrical body of the spacer.

[0009]

[Effect of device]

 According to the water-containing liquid and liquid fuel magnetic reforming device (magnetizing device for simplicity) of the present invention, water, tea, liquor, and other beverages are used according to the water and other liquids that have been reformed (magnetized). It has the effects of improving the taste of vegetables, promoting the growth of vegetables such as eggplant, and improving the energy content of liquid fuel. It is understood that these are because the treated liquid is magnetized and activated in a broad sense, and therefore the magnetizing device of the present invention can be used for drinking water, favorite beverages, fruit juices, alcoholic beverages, medical water, agricultural and livestock water, and industrial water. It can be widely applied to water-containing liquids such as water and precision industrial water, or liquid fuels such as heavy oil, petroleum, kerosene, and gasoline. For example, there is data that curing a cement composition using magnetized water (mortar, concrete, etc.) improves the strength of the cured product.

[0010]

[Action]

 Although the operation of the magnetizing device of the present invention is not necessarily clear, it is not intended to limit the present invention theoretically.However, for example, it is delicious when treating drinks such as water and alcoholic beverages under certain conditions. In a broad sense, "magnetization" action occurs, such as the action of magnetism to cause phenomena such as the decomposition of water molecule clusters, or the resulting improvement in the compatibility (compatibility) with water and alcohol or fruit juice. It is speculated that it is because of this. In addition, because the thermal power (contained energy) of liquid fuel improves and the growth of plants that supply treated water is promoted, it is possible that water or liquid is activated (“magnetized”) in some way. It is supposed that there is. However, in order to magnetize or activate the water-containing liquid and the liquid fuel according to the present invention, a magnetic field is not simply applied, but a specific magnetic field is required. It is important to pass between double-cylindrical magnets with four or more poles, and it is particularly effective to apply a magnetic field of 5000 G or more, and further 7,000 G or more.

[0011]

【Example】

 An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a vertical sectional view and a horizontal sectional view of a magnetizing device of the present invention. In FIG. 1, 1 is a spacer, 2 is a magnetic circuit forming shield ring, 3 is an outer magnet, 4 is an inner magnet, 5 is a core, and 6 is a cap. 2 shows a spacer, FIG. 3 shows a magnetic circuit forming shield ring and an outer magnet, FIG. 4 shows an inner magnet and a core, and FIG. 6 shows a cap.

The spacer 1 is inserted between the outer magnet 3 and the inner magnet 4 to prevent the inner magnet 4 from being eccentric in the outer magnet 3 to attract each other. Referring to FIG. 2, the spacer 1 has a partition wall 1c between the outer cylinder body 1a and the inner cylinder body 1b for maintaining the distance between these double cylinder bodies. In this figure, the partition wall 1c is formed so that three flat plates that are long in the axial direction extend in the radial direction at intervals of 120 °, but the shape, size, number, and arrangement are not particularly limited. It suffices if a space for flowing the liquid can be formed and maintained between the outer cylinder 1a and the inner cylinder 1b. Further, the outer cylinder 1a and the inner cylinder 1b only need to be able to separate the outer magnet 3 and the inner magnet 4, and the circumferential portion of the cylinder does not need to be continuous and may be formed of a skeleton and may be perforated. . One end of the inner cylindrical body 1b is closed by a hemispherical cap-shaped portion, and the liquid flowing from the top side of this hemispherical cap-shaped portion is guided to the gap between the outer cylindrical body 1a and the inner cylindrical body 1b. You can The shape of the cap-shaped portion is not limited to a hemispherical shape, and it suffices that the central portion protrudes to guide the liquid between the cylindrical bodies. The formation of the cap-shaped portion is not essential.

Each part of the spacer 1 is preferably integrally formed. As a method of integrally molding, in addition to cutting out from the cylindrical body by electric discharge machining or other method, resin may be molded by injection molding or other method. In addition, the outer cylindrical body 1a, the inner cylindrical body 1b, and the partition wall 1c may be separately formed and then integrated by bonding, welding or other means. The material of the spacer 1 is a non-magnetic material, and examples thereof include metals such as true casting, aluminum and pure non-magnetic stainless steel, and plastics such as polyethylene, polypropylene, urethane, PET and fluororesin which are harmless for beverages. can do.

Since the magnetic circuit forming shield ring 2 as shown in FIG. 3 constitutes a magnetic circuit, it is preferably made of a magnetic material such as steel and arranged on the outer circumference of the outer magnet 3 to be used as a magnetic shield. A certain thickness or more is required to act as a magnetic shield. However, a ring may be arranged on the outer circumference of the outer magnet 3 to be used as a holding means or a protecting means for the outer magnet 3, in which case a non-magnetic material may be used, and the thickness is not limited. A magnetic material suitable for the magnetic circuit formation shield may be any magnetizable material that can confine the magnetic field generated from the outer magnet 3. The outer magnet 3 is preferably press-fitted and held in the ring 2.

The outer magnet 3 is shown in FIG. 3 and has a cylindrical shape. In the present invention, it is necessary to have 4 or more magnetic poles in the cross section, and 4 poles, 6 poles or 8 poles are preferable. It is possible to magnetize the cylindrical body into two poles with N poles and S poles in each half circumference in the cross section, but the effect of the present invention could not be obtained with the two poles. Magnetization with four or more poles can be performed by forming a magnet material into a cylindrical shape, and then arranging a magnetizing device with a corresponding number of magnetic poles on the outside of the cylinder to apply a magnetic field. The two-pole magnets may be manufactured by collecting them in a cylindrical shape and fixing them. In the present invention, the magnetic field strength generated between the outer magnet 3 and the inner magnet 4 is preferably 5000 G or more, more preferably 7,000 to 10,000 G. It was found that the present invention exerts a remarkable effect by applying a stronger magnetic field than that obtained with an ordinary magnet. The manufacturing method itself of such a strong magnet is known. As a material for the outer magnet 3 and the inner magnet 4, for example, a ferromagnetic material such as neodymium, a magnet, or a sodium cobalt magnet can be used. The cylindrical outer magnet is preferably magnetized from the inside. In the present invention, only the inner side or the outer side in the cross section of the outer magnet may be magnetized. It is clear that inner magnetization is advantageous because it is closer to the working surface.

As shown in FIG. 1, the axial lengths of the magnetic circuit forming ring 2 and the outer magnet 3 are shorter than that of the spacer 1, so that the magnetic reforming device of FIG. Or it is advantageous when connecting. Referring to FIG. 4, the inner magnet 4 is inserted inside the spacer 1 and has the same number of magnetic poles as the outer magnet 3 in the cross section so as to form a magnetic field between the inner magnet 4 and the outer magnet 3. It can be the same as the outer magnet 3 except that when the three and the inner magnets 4 are arranged in a double cylindrical shape, the magnetic poles of the opposing circumferential surface portions are reversed. FIG. 6 shows the arrangement relationship between the outer magnet 3 and the inner magnet 4. That is, the magnetic poles of the corresponding portions of the outer magnet 3 and the inner magnet 4 are reversed between N and S. Since the inner magnet 4 attracts the outer magnet 3 and can be enclosed by the cap 6 in the spacer 1, it is not necessary to press-fit it into the spacer 1. The outer magnetizing method is preferable as the magnetizing method for the inner magnet.

FIG. 4 shows the core 5. Practically, it is preferable to dispose the core 5 in the inner magnet 4 to form a magnetic circuit for increasing the surface magnetic field, because it is more effective. The core 5 is made of a magnetic material having a cylindrical shape, and is, for example, a steel material (iron), and is press-fitted into the inner surface of the magnet during manufacturing. The core 5 is preferably press-fit into the inner magnet 4.

Referring to FIG. 5, the cap 6 is mainly used for accommodating the inner magnet 4 and the core 5 in the spacer 1. The cap 6 also has the function of organizing the flow path of the liquid flowing on the cap 6 side. May be. 2 and 5, the radius of the hemisphere (projection) of the spacer 1 of FIG. 2 is smaller than the radius of the hemisphere (projection) of the cap 6 of FIG. 5, but they are equal to each other, You may reverse. The cap 6 is made of a non-magnetic material, and can be made of the same material as the spacer 1. After inserting the inner magnet 4 and the core 5 into the spacer 1, the cap 6 is usually integrated with the spacer 1 by means such as adhesion or welding.

As described above, the outer magnet 3 is press-fitted in the magnetic circuit forming shield ring 2, the core 5 is press-fitted in the inner magnet 4, and the spacer 1 is interposed between them to arrange them in a double cylinder shape. Then, the outer magnet 3 and the inner magnet 4 are integrally held together by the magnetic attraction force. Further, when the cap 6 is attached to the spacer 1, the magnetizing device as shown in FIG. 1 is completed.

The size of each member is not particularly limited, but, as an example, the outer diameter of the spacer 1 is 30 mm, the inner diameter is 20 mm, the wall thickness is 0.7 mm, the length is 50 mm, the hemispherical portion radius is 10 mm, and the magnetic shield ring is an approximate number. 2 outer diameter 45 mm, inner diameter 36 mm, length 35 mm, outer magnet 3 outer diameter 36 mm, inner diameter 30 mm, length 40 mm, inner magnet 4 outer diameter 20 mm, inner diameter 14 mm, length 30 mm, core 5 outer diameter 14 mm, The length is 30 mm and the radius of the spherical surface of the cap 6 is 12 mm. In particular, the distance between the outer magnet 3 and the inner magnet 4 is not limited, but for example, about 1 to 3 mm is simple and preferable.

As a method of using this magnetizing device, the magnetizing device may be simply inserted and connected in the middle of the liquid conduit, or may be arranged inside a special liquid processing device having a liquid tank and the like together with a pipe. The preferred embodiment of the present invention has been described above, but the present invention is not limited to this specific example.

Next, an example in which the effect of the present invention is confirmed by using the magnetizing device of FIG. 1 will be described. Pipes were connected to both ends of the spacer 1 of the magnetizing device of FIG. 1, and various kinds of liquids were passed through the pipes between the inner and outer magnets of the device of FIG. 1 to obtain a treated liquid. These treated liquids were evaluated according to various liquids. Hereinafter, the liquid subjected to this treatment (modification) is referred to as a "magnetized" liquid.

When the magnetized tap water was tasted with the same non-magnetized tap water, the magnetized tap water felt delicious. Then, when about 100 people tasted it in the same manner, the majority of people admitted that the water had become delicious. Similar evaluations were carried out for sake and tea, but it was also found that the magnetization caused the taste to become mellow and delicious.

When the same evaluation was performed on fruit juices such as tomato juice, kiwi fruit juice, and orange juice, it was evaluated that the sourness decreased due to magnetization and the sweetness increased. From these, it is recognized that the beverage containing water is treated with the magnetizing device of the present invention to be delicious. Surprisingly, it was also confirmed that in the magnetizing device as shown in FIG. 1, the number of magnetic poles of the magnet needs to be four or more, and when the number of magnetic poles is two, the above effect cannot be obtained, which is rather bad.

In addition, tap water that was not magnetized was given to a part of vegetable plants such as eggplant and tomato grown in the same place, and tap water that was magnetized was given to the plant next to it. Plants fed with tap water promoted the growth of 20 to 30%. Furthermore, when the magnetizing device shown in Fig. 1 was inserted in the middle of the boiler refueling pipe to measure the combustion of the boiler with or without magnetizing the heavy fuel oil, the combustion of the boiler was measured. It was confirmed that the efficiency (combustion energy) was improved. It has been confirmed that the same effect can be obtained with kerosene, gasoline, etc. without changing the physical properties.

It was also necessary that the number of magnetic poles of the magnet was 4 or more. The above evaluation was carried out with a magnetic field strength of 5000 to 10,000 G, and the effects were recognized in all cases. It was particularly good at 7,000 to 10,000 G. It seems that the effect is poor at about 1000 to 2000 G.

[Brief description of drawings]

FIG. 1 is a vertical sectional view and a horizontal sectional view of a magnetic reformer for water-containing liquid or liquid fuel according to an embodiment of the present invention.

FIG. 2 is a vertical sectional view and a horizontal sectional view showing a spacer.

FIG. 3 is a vertical cross-sectional view showing a magnetic shield ring and an outer magnet.

FIG. 4 is a vertical cross-sectional view showing an inner magnet and a core.

FIG. 5 is a side view showing a cap.

FIG. 6 is a cross-sectional view showing a positional relationship between an outer magnet and an inner magnet.

[Explanation of symbols]

 1 ... Spacer 2 ... Magnetic circuit forming shield ring 3 ... Outer magnet 4 ... Inner magnet 5 ... Core 6 ... Cap

Claims (11)

[Scope of utility model registration request] 1. A cylindrical magnet having four or more magnetic poles in a cross section is arranged and held so that the magnetic poles of the corresponding portions of the inner and outer cylinders are doubled inside and outside. A magnetic reformer for water-containing liquid or liquid fuel, characterized in that the water-containing liquid or liquid fuel is magnetically reformed by passing between the cylindrical magnets. 2. A water-containing liquid or liquid between the double cylindrical magnets, wherein a spacer made of a non-magnetic material having a double cylindrical body and a partition wall therebetween is interposed between the inner and outer cylindrical magnets. The apparatus for magnetically reforming a water-containing liquid or liquid fuel according to claim 1, which forms and maintains a gap through which the fuel flows. 3. The magnetic reformer for water-containing liquid or liquid fuel according to claim 1, wherein a cylindrical body made of a magnetic material is inserted into the inner cylindrical magnet to form a magnetic core. 4. A magnetic reformer for water-containing liquid or liquid fuel according to claim 1, wherein an outer cylindrical magnet is inserted into a cylindrical body made of a magnetic material to form a magnetic circuit. 5. The magnetic field strength between the double cylindrical magnets is 5000.
The magnetic reformer for a water-containing liquid or liquid fuel according to any one of claims 1 to 4, wherein the magnetic reformer is in the range of 1 to 10,000 G. 6. The magnetic field strength between the double cylindrical magnets is 7,000.
The magnetic reformer for water-containing liquid or liquid fuel according to claim 5, wherein the magnetic reformer is in the range of ˜10,000 G. 7. The magnetic reforming of the water-containing liquid or liquid fuel according to claim 1, wherein the number of magnetic poles in the cross section between the double cylindrical magnets is 6 or 8. apparatus. 8. The inner cylindrical magnet is capped at least at one end in the axial direction, and the cap has a shape in which a central portion of an axial line of the cylindrical body is a top portion and the cap is lowered toward a circumferential portion of the inner cylindrical magnet. The water-containing liquid according to any one of claims 1 to 7, which acts to guide the flow of the water-containing liquid or liquid fuel toward the one end side of the cylindrical magnet into the gap between the double cylindrical magnets. Liquid fuel magnetic reformer. 9. The magnetic reformer for water-containing liquid or liquid fuel according to claim 1, which is a magnetic reformer for water or liquor. 10. A spacer made of a non-magnetic material, wherein a partition is provided between the outer and inner double cylinders, and one end of the inner cylinder is closed. The inner cylindrical magnet is arranged inside the cylindrical body, and the cap made of a non-magnetic material at the portion closing one end of the inner cylindrical body of the spacer or the other end enclosing the inner cylindrical magnet in the inner cylinder of the spacer is the axis line. Since the central portion has a shape projecting outward in the axial direction, it has the function of guiding the flow of the water-containing liquid and the liquid fuel toward the one end of the inner cylindrical magnet into the gap between the double cylindrical magnets. The inner and outer cylindrical magnets each have four or more magnetic poles in the cross section and are arranged so that the magnetic poles of the corresponding portions of the inner and outer cylinders are opposite to each other. Between the magnets
A magnetic field of 000 G or more is generated, a magnetic material cylindrical body is placed outside the outer cylindrical magnet to be magnetically shielded, and a magnetic material cylindrical body is inserted into the inner cylindrical magnet to form a magnetic core. A magnetic reformer for water-containing liquid or liquid fuel, characterized in that the liquid or liquid fuel is passed between these cylindrical magnets to be magnetically reformed. 11. The spacer according to claim 2 and one cap having the shape according to claim 8 are integrally formed, and the cap having the shape according to claim 8 is attached to the other end of the spacer. A member for a magnetic reformer of a water-containing liquid or liquid fuel, wherein an inner cylindrical magnet and a core can be inserted inside the inner cylinder of the spacer.