JPS63174669A - Vibration type simple magnetic health device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] [Object of the invention 1 (b) Industrial application fields The present invention relates to health appliances that utilize magnetism.

(b) Conventional technology The use of magnetic irradiation to treat stiff eyebrows, etc. is already a popular health method.

The simplest method is to attach a permanent magnet to clothing or jewelry, or directly attach it to the skin using adhesive tape, so that a static magnetic field is constantly applied to the body.

(c) Problems that the invention attempts to solve The present invention aims to enhance the medical effects of this magnetism.

Although the medical effects obtained by irradiating magnetic fields are not necessarily scientifically clear, they have already been used in many fields and their effects have been confirmed. The physical magnetic phenomenon related to this is the generation of Lorentz force. That is,
The body contains many ions and charged colloidal particles in blood, lymph fluid, nerve fibers, etc. When these charged particles move in a static magnetic field with the flow of body fluids, they are subjected to Lorentz force, resulting in a stirring effect. As a result, the circulation of body fluids such as blood circulation is improved, or the so-called acupuncture points are improved! ￥
, W1. It is believed that this contributes to providing an appropriate stimulus for the conduction of ions within a.

However, from the above point of view, in order to obtain a stirring effect, there must be sufficient flow of body fluids, but in areas where muscles are exhibiting symptoms such as stiffness, body fluids are flowing due to the accumulation of waste products. There is a strong tendency for circulation to be stagnant, and in this case, the Lorentz force that provides the stirring effect is not sufficiently generated. Another way to create a force that has a stirring effect on charged particles is to vary the magnetic field according to the principles of electromagnetic induction. Simply placing a magnet on the body's surface can only create a static magnetic field, but using an appropriate electromagnetic device, for example, could produce a fluctuating magnetic field, making it even more effective. A method similar to this is
Methods such as irradiating the body surface with low-frequency or high-frequency waves or passing weak alternating current into the body are already in widespread use, and the existence of effects has been confirmed, similar to the case of holding fixed magnets.

However, methods using such devices are not only expensive but also have poor portability, and cannot apply magnetism to the body at the time. It does not extend to just holding it.

In view of the above-mentioned reasons, the present invention presents a method for simply applying a variable magnetic field without preparing a particularly large device.

[Structure 1 of the Invention (d) Means for Solving the Problems The present invention applies a fluctuating magnetic field to the body surface by moving a small permanent magnet. No external power is used to move the small magnet. By holding a magnet on or near the body, it takes advantage of the fact that the magnet moves or vibrates as the body moves.

The structure of the present invention consists of a capsule container holding a permanent magnet therein, and a permanent magnet movable within the capsule container. Being mobile refers to the displacement that the body undergoes due to daily body movements, such as running, standing, sitting, turning over while sleeping, etc.
This means that it moves in response to vibrations. It works by placing this capsule container on or near the body surface. The positioning method does not matter, but methods such as traditional fixed magnet methods used to hold permanent magnets, attaching them to clothing, accessories, or bedding, or attaching them to the body surface using adhesive tape are available. It can be used as is. The capsule container is used to isolate the magnet from clothing, the body, etc. so that its movement is not obstructed by clothing, the body, etc., and like the magnet held within it, its size and shape are not specified. Further, it does not necessarily have to be a sealed container, and as long as the structure is sufficient for isolation, the container may have a mesh like a bar or a structure consisting only of an outer frame.

The magnet needs to be movable within the capsule container due to vibrations that the capsule receives from daily body movements, but the structure and degree of freedom of movement for this purpose are not specified.

(E) Effect The permanent magnet inside the capsule moves with the movement of the body, applying a fluctuating or oscillating magnetic field to the body surface and the body near the surface,
In addition to the effect of static magnetic field irradiation using a conventional fixed magnet, the magnetic effect is enhanced by providing an induction effect.

(f) Example It seems that placing the magnet as close to the body surface as possible will increase the magnetism received by the body and will be more effective.If the bottom is the surface parallel to the body surface, then the bottom area of the capsule container should be A flat columnar type that is large compared to its height is highly practical.

The one shown in Fig. fjS1 and Fig. 2 has a freely moving spherical magnet placed inside a flat cylindrical capsule container.
The height of the inside of the cylinder approximately corresponds to the α diameter of the magnetic sphere. Fig. 1 shows a plan view, and Fig. f52 shows a side view. The diameter of the cylindrical bottom is moderately larger than the diameter of the sphere, and the structure allows the ball to roll along the bottom.

The plan view shown in Fig. 3 and the longitudinal sectional view shown in Fig. fjrJ4 are examples in which a spring is attached to the magnet to prevent it from coming into direct contact with the capsule container1, and the degree of freedom of movement is limited to one direction. . A plate spring is used as the spring, and the magnet vibrates in the direction of the plate thickness. As shown in the figure, a flat magnet is attached so as to be wrapped around one magnet fixing plate part 34 of an elongated metal plate that is the material of the spring, and the other part is bent into a "" shape to form a vibrating part fixing push plate part 33. If this structure is fitted appropriately into the inner wall of the capsule container, manufacturing costs and one step can be reduced. A plate spring portion 31, which is an intermediate portion between a portion 34 that holds the magnet and a portion 33 that fixes the entire capsule to the capsule container, functions as a spring. The magnet receives external vibrations and vibrates at a unique frequency, but because it uses a leaf spring, its direction is always parallel to the bottom of the capsule container and cannot move in any other direction. , the magnet will not touch or collide with the inner wall of the capsule container and the vibration will not be disturbed. Compared to the structures shown in Figures 1 and 2, it takes more effort to attach the leaf spring, but there is no sound of the magnet rolling inside the capsule container, and the vibration caused by the spring can speed up the movement of the magnet. Then, the changes in the magnetic field lines experienced by charged particles inside the body that are affected by magnetism become larger,
It has the advantage that it can be expected to increase the stirring effect according to the laws of electromagnetism.

According to the mechanics of materials, the following relationship exists between the force F applied to the tip of a leaf spring and the moving distance X in the plate thickness direction, which is the vibration direction of the tip.

Eb3 F= −−−−X −−−−−−−−−−
-----(1) In 41 Kouni, a, b, and I are the width, thickness, and length of the leaf spring, respectively, and E is the Young's modulus of the material of the leaf spring.

The E of many metals is about 10"81m2.(1)
The coefficient of X in the equation corresponds to the spring constant of the leaf spring.

-The acceleration that all human beings experience during their normal daily movements is
The inertial force applied to the magnet at this time corresponds to F in equation (1), which is approximately 0.19 to 1.09 relative to the gravitational acceleration 9. The permanent magnets currently on the market as magnetic health devices using conventional fixed magnets are as small as 0.2 grams. Hereinafter, a” 1 jam, b=0.02
ff++n+ l== 2 mm, E=1 ONN
/l112, when the body obtains an acceleration of 0.59 for a certain period of time, X1, that is, the maximum amplitude of the leaf spring, is estimated from equation (1), and it becomes X=~0.2■. Furthermore, assuming that the magnet attached to the leaf spring takes the form of an ideal simple harmonic motion, the period at this time is 0.04 seconds, the frequency is 25 Hz,
The maximum speed of the magnet is 0.031111/s. The magnet is perpendicular to the body surface at 1000 Hauss (0, IWb/+2
), then if we take the product of both, this gives us a local maximum of ~3 X 10-'V parallel to the body surface.
An electric field of /m will be formed.

In general, in equation (1), the smaller the coefficient of becomes larger. In order to reduce the value of this spring constant, instead of using a single plate-shaped leaf spring as shown in the example, it is necessary to use a wave-like or serpentine-like shape instead of a flat shape, or to use a torsion spring instead of a flat spring. There are methods such as using a coil spring or using plastic or elastic rubber instead of metal for the leaf spring. When using a coil spring or elastic rubber, the ability to limit the degree of freedom of movement is reduced, so contact between the vibrating magnet and the inner wall of the capsule is possible. It may be necessary to consider such things as creating a shape that has less friction, or providing a motion guidance function to limit the degree of freedom.

The plan view in Figure 5 is related to Figures 3 and 4 (71), and when a spring with a small spring constant or a somewhat thick H magnet is used, two holding springs are used. The figure shows a structure in which a magnet is supported using a magnet.If the size of the magnet is further increased, a structure in which three or four springs are provided is also possible.

The one shown in FIG. 6 is a plan view and in FIG. 7 is a vertical cross-sectional view. A fixed shaft 61 is provided as a guiding function for the movement of the magnet, and the magnet is rotated around this shaft. and attach it to the fixing ll1161. Figures 6 and 7
Although the example in the figure does not use a spring,
It is also possible to combine it with a suitable spring in conjunction with the example shown. In FIGS. 6 and 7, a part of the magnet is located on the axis of rotation, and the material that makes up the fixed shaft 61 does not penetrate the magnet, but if possible in the process, it is possible to make a hole in the magnet. Alternatively, it is also possible to arrange the magnet further toward the end and provide a fixed shaft that passes through the magnet without being obstructed. However, if the eccentricity is increased, the container will become larger for a magnet of the same size, so an appropriate shape should be selected.

The material of these capsule containers is not particularly limited, but those made of plastic are easy to manufacture and inexpensive. It is not necessary that the entire capsule container be constructed of the same material. In order to measure the close contact between the magnet and the body surface, it is better to have a thin wall at the bottom of the capsule container, but if a highly conductive material is used, the fluctuating magnetic field will be shielded due to the generation of eddy currents, and the wall thickness at the bottom of the capsule will be thin. It is best to avoid metal plates as they may not reach the target.

There are no restrictions on the material of the magnet, but in recent years various compact and strong magnetic materials have been developed. Small magnets used in conventional fixed magnets to provide a silent magnetic field can be used as they are in the present invention.

[Effect of the invention 1 (g) Effect: irradiating a fluctuating or oscillating magnetic field into the body through the surface of the body,
Provides a greater magnetic effect than the traditional method of simply carrying a fixed permanent magnet. It has a simple structure that does not require any special electromagnetic equipment, and compared to the conventional fixed magnet method, the size is about the same as turning the magnet around, so it can be carried around in the same way as a fixed magnet. It can have a constant effect on the body.

[Brief explanation of the drawing]

Figure PIIJi is a plan view of a configuration using movable spherical magnets in one embodiment of the present invention. FIG. 2 is a side view of the same example as FIG. 1. FIG. 2 is a plan view of an embodiment of the present invention in which a magnet is vibrated by a leaf spring. FIG. 4 is a longitudinal sectional view of the same example as FIG. 3. FIG. 5 is a plan view of a configuration in which the number of springs is increased in the configurations according to tjS3 and FIG. 4. FIG. 6 is a plan view of an embodiment of the present invention in which a magnet is rotated around a fixed axis. fj
Figure S7 is a side view of the same example as Figure 6. 7 -1---Capsule container 10---One container inner cavity 11---One container side wall 12---One spherical magnet 21---One container bottom wall 31---Rice spring part 32 ---- One flat magnet 33 ---- One vibrating part fixing press plate part 34 - Magnet fixing plate part 35 - One one Magnet stopper 61 - One fixed pongee 62 - --- One intermediate ring 71 --- One magnet retaining plate Patented by Mitsutoshi Kayajima Figure 7 Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Figure 7 Procedural amendment - (Method) % formula % [ 5. Date of amendment order March 31h6, 1985, Countermeasures for amendment Column 7 for a brief explanation of drawings in the specification, Contents of amendment 7th line from the top of page 12 of the specification: ``Side view.''

Claims (2)

[Claims] (1) A magnetic health device containing a movable permanent magnet inside a capsule container. (2) A permanent magnet is fixed to the other end of a plate spring whose one end is fixed to the wall of the capsule container or a device having an equivalent function so as to be able to vibrate parallel to the bottom surface of the capsule container (1) Magnetic health device related to.