JPH09115723A - Nondirectional attracting magnetic sphere - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the effect to ensure always automatically the attracting state of different poles N and S, by forming small-sized objects which produce intensive magnetic lines of force, and preventing the reaction of the same N poles and the reaction of the same S poles. SOLUTION: A magnet is isolated from an object containing the magnet. In a spherical body having a desired form, an intensive separate magnet 6 is inserted. A cavity 5 in the spherical body is the active space of the magnet. When two spherical bodies approach each other, different poles N and S of the magnets in the spherical bodies exhibit mutually attractive function. The magnets rotate in the inside cavities and attract both spherical bodies. By assembling each component after the whole process is finished, magnetization during the process is prevented. New material superior to ferrite is used to improve performance.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION It is a theorem that a magnet has a property in which an N pole and an S pole form a pair, the same pole repels, and different poles attract each other. Therefore, the following three patterns are possible. In the first pattern, when the N poles face each other, the N poles repel each other according to the theorem. The second pattern is S pole and S
When the poles face each other, the same pole repels with this theorem.
The third pattern is when the north pole and the south pole face each other. At this time, both polarities are attracted because the theorem has the property of attracting different polarities. Of these three patterns, the third pattern emerges from the N pole and spreads out in space due to the movement of the lines of magnetic force.
The magnetic effect is exerted by repeating the motion of gathering at the south pole, passing through the magnet and returning to the north pole. During this period, it stimulates peripheral nerves by means of electrical and magnetic attraction, strengthens and promotes the function of blood circulation, and is therefore a target for health appliances. The present invention is such that, by inserting a magnet into the inner surface of a sphere, when two spheres approach each other, the N and S both poles are always instantly attracted in all directions regardless of the approaching directions. The present invention relates to an omnidirectional adsorption magnetic sphere for health appliances. The cavity provided on the inner surface of the sphere is a space in which the N and S poles of the inserted small magnet can freely rotate and float. Since the sphere is made of a non-ferrous material, for example, a non-ferrous metal that does not attract magnetism, or a material such as a synthetic resin, the space inside the sphere becomes a floating floating space of the magnet and becomes an active space without being magnetically attached to the sphere. The magnet is not magnetically attached to the sphere, but when two spheres loaded with the magnet come close to each other, the different poles are instantly attracted and attracted by the action of the magnetic force. For example, when there is an N pole on the side surface of the A sphere, even if the magnet in the B sphere faces the same pole, the S pole is turned around by magnetic force and attracted, and both spheres are attracted. The same phenomenon occurs in the opposite case, and the N and S heteropolar adsorption effects are similarly obtained with other combinations. That is, according to the present invention, in any case, regardless of the theorem of homopolar repulsion of the magnet, it is possible to always obtain the heteropolar attraction effect suitable for the health appliance.

[0002]

2. Description of the Related Art Conventionally, a magnet is a ferrite magnet, but a ferrite magnet is iron oxide and refers to red rust. It is a compound magnetic material mixed with sub-materials and is used for toys and teaching materials, but it has a weak magnetic force as a magnetic material. In addition, due to quenching, the product thickness is limited to 3 mm, and there are technical limitations in molding, so it is mainly suitable for plate-shaped, rod-shaped, horseshoe-shaped products. There is a difficult condition that you have to put it in an electric furnace and burn it at an ultra high temperature of about 1700 to 1800 degrees Celsius for about 20 hours, like pottery. Therefore, these constraints are also constraints on the production of health appliances. First of all, the mold can only be made in a simple shape, so it is not suitable for health appliances where diversity is desired. Second, it must be able to withstand ultra-high temperature quenching, which makes the mold expensive and not economical. Thirdly, the product can be molded only from solid ones made of ferrite, so even if it is shrunk to a small size, it has a considerable weight. Fourth, the product has the N and S poles fixed on the front and back, so
In order to obtain the different poles of S, an operation of avoiding the same poles that always repel each other is required. In these senses, it cannot be overlooked that ferrite magnets contain many elements that are not practical for health appliances. Heretofore, there have been medical products for magnetic materials in the form of umeboshi, which are in the form of umeboshi. The present invention complements these deficiencies and provides a product with an unprecedentedly strong magnetic effect.

[0003]

The first problem is how to make an object having a small shape and obtaining a strong magnetic field line. The second problem is how to prevent the repulsion of N, N homopolar and S, S homopolar, and automatically
Is it possible to switch to the S pole. The third problem is that since magnets are attracted by different polarities of N and S, the semi-finished products are attracted to each other in production and the finishing work becomes difficult. For mass production, it is essential to solve this production problem. The fourth problem is that new products for magnets of all advanced levels are being developed, and the use of materials that exceed the performance of conventional ferrite magnets must be reconsidered. The fifth problem is to solve the above problems and find an economical measure suitable for mass production.

[0004]

[Means for Solving the Problems] The following five means can be considered for solving the problems to be solved by the invention. First of all, it is difficult to commercialize the product by strengthening only the magnet itself and it is difficult to commercialize it. Therefore, it is necessary to separate the magnet itself and the object into which the magnet is placed. That is, to insert a strong solid magnet into the desired sphere. Secondly, the magnets loaded in the two spheres turn around in the inner cavity because the N and S different poles of the spheres exert their attraction function when the spheres approach each other.
Adsorb on demand. As a result, it is possible to avoid homopolar repulsion between the N and N poles and the S and S poles. Thirdly, the magnet is loaded on the inner surface of the sphere, but the magnetic attraction between the spheres of the product must be avoided. Therefore, many jigs are required for finishing such as painting and plating in the conventional methods. If a magnet that is magnetized from the beginning is loaded, the semi-finished products will be attracted to each other, resulting in non-finished products. If you insert a magnetic body of a magnet that is not magnetized and magnetize the finished product, you will need many jigs unlike the simple form, and you will find that there are difficulties in the production process. Absent. It is undeniable that there are many problems in production not only when magnetized first, but when magnetized later. Fourth, in recent years, compared to conventional ferrite magnets,
Magnetic materials that make strong magnets have been developed one after another. For example, cobalt, tungsten, chrome and alloys were invented, and further inventions such as samarium cobalt and neodymium magnets exceeding ferrite were brought. In the present invention, the neodymium magnet is optimally adopted by paying attention to the correlation between the size of the shape and the strength of the magnet. Fifth, the following comprehensive measures are taken as means for solving the problems from the viewpoints of the mass productivity of products and the economical efficiency of production. Due to the difficulty of sphere finishing, which requires a lot of jigs, the sphere is divided into two equal parts and molded, and the finish painting or plating is completed.
Finally, the desired magnet is loaded and the two broken magnet spheres are fitted and bonded. By doing so, it is possible to avoid the complexity of the pre-magnetization and the post-magnetization of the magnetic material, and it is possible to mass-produce a variety of inexpensive and beautiful desired products.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION Since a walnut has conventionally been gripped in the palm or rubbed with fingers to serve as a substitute for a health appliance, a walnut-shaped product having a walnut shape is adopted as one of the embodiments. did. First, a walnut-shaped product is molded as if it is divided into equal parts, a strong neodymium magnet of 4,000 gauss is charged therein, and then both of the divided case-deformed hemispheres are fitted. Since one sphere has 4,000 gauss, two opposing spheres form a case-shaped strong magnetic sphere with strong magnetic field lines of 8,000 gauss. The volume of a strong neodysium magnet of 4,000 gauss is a small magnet with a straight stem of 8 mm and a height of 8 mm. In addition to this, a perfect circle sphere, a golf ball sphere, a soccer ball sphere, and the like are also examples, and various colors can be expressed by painting or plating.

[0006]

EXAMPLE A case-shaped deformed sphere is divided into two halves to form a hemisphere, and a hemisphere cavity is formed with the thickness of the sphere wall left as shown in FIG. Next, as shown in FIG. 2, a hemispherical cavity is formed by leaving the thickness of the spherical wall, and a concave fitting peripheral edge corresponding to the convex fitting peripheral edge of FIG. 1 is provided as a female mold. Before fitting the hemisphere of FIG. 1 and the hemisphere of FIG. 2, a required strong small magnet is inserted and both hemispheres of FIG. 1 and FIG. 2 are fitted to form the case-shaped deformed sphere of FIG. To do. Each part of the case-shaped deformable sphere is plated with gold or platinum before fitting, and the finishing is completed through the process of hard transparent electrodeposition coating, so that the product is completed by the fitting of FIGS. 1 and 2. For example, a perfect circle sphere, a golf ball-like sphere, a soccer ball-like sphere, or any other shape can be used in this manufacturing method.

[0007]

EFFECTS OF THE INVENTION The same pole repels and the opposite pole attracts. This is a magnet theorem, and everyone knows how such magnets work. Although this theorem cannot be overridden by anyone, the practical effect contrary to this theorem can be obtained by the effect of the invention. This is the object of the present invention and the effect of the invention. Contrary to the theorem, avoiding the repulsion of the same pole, it always automatically asked for the adsorption of the opposite pole. It is also a remarkable effect of the present invention that a strong magnet effect can be obtained by inserting a small and powerful magnet. The action of the magnetic force lines of the powerful magnet spreads out from the N station to the space, gathers at the S pole, and further passes through the magnet to the N pole. The magnetic field line repeats this operation. Since the adsorption action of the different poles induces the action of the magnetic field lines, the present invention has been able to obtain effective results by focusing on the adsorption effect of the N and S different poles. It is an invention that is unprecedented in that it is built in. It should be noted that it is also an effect of the invention to be noted that there is room for obtaining a high-power magnet sphere capable of strengthening the magnetic flux density more than this, if necessary.

[Brief description of the drawings]

1 is a cross-sectional view of a male hemisphere.

FIG. 2 is a sectional view of a female hemisphere.

[Fig. 3] Assembly cross-sectional view Cross-sectional view of male-female mating spherical body

[Explanation of symbols]

 1 Male hemisphere cross section 2 Male hemisphere fitting convex edge cross section 3 Female hemisphere cross section 4 Female hemisphere fitting concave edge cross section 5 Both hemisphere fittings 1 and 3 Cavity in cross section of the sphere after 6 Small magnet that tumbles and floats in the cavity inside the sphere

Claims (1)

[Claims] 1. A hemisphere made of a non-ferrous material formed by dividing a sphere into two cavities, each of which has a cavity in the sphere leaving only the thickness of the sphere wall, and a powerful small magnet is inserted therein. , A structure of a magnetic sphere in which two hemispheres are fitted to each other to form a cavity on the inner surface of the sphere, and a magnet inserted allows free rotation and floating in the cavity.