JPH034397Y2 - - Google Patents

Description

[Detailed Description of the Invention] <Industrial Application Field> This invention relates to a magnetization processing device that performs magnetization processing on fluids such as water and oil to improve the quality of the fluids.

<Prior Art> In recent years, devices have been proposed that improve water quality by applying a magnetic field from a permanent magnet to drinking water, for example. In particular, as this type of device, a magnetized bottle having a structure in which a plurality of permanent magnets are suitably arranged on the peripheral wall of the container has been proposed, and the magnetic field of these permanent magnets is applied to the drinking water in the container.
It is working to revitalize water.

<Problem that the invention aims to solve> However, in the case of a magnetized bottle with such a structure, the magnetic field formed inside the container is a static magnetic field and the magnetizing effect is weak, so the water cannot be activated effectively. There is a problem in that the water quality improvement effect cannot be fully expected.

This invention was made with attention to the above problem, and the purpose is to provide a new magnetization processing device that can effectively activate fluids such as water by rotating the magnetic field formed inside the container. .

<Means for Solving the Problems> In order to achieve the above object, this invention includes a bottle body comprising a container having a spout and a rotating body rotatably supported inside a container having a plurality of permanent magnets; A magnetization processing device is configured with a bottle drive section having a bottle support surface for supporting the bottom surface of the bottle body on the top surface of the case and a motor as a drive source housed inside the case.

The bottle drive unit includes a rotary plate attached to the output shaft of the motor parallel to the bottle supporting surface, a plurality of permanent magnets arranged at predetermined angular positions on the upper surface of the rotary body, and rotation of the inside of the bottle body. A permanent magnet was placed at the lower part of the body, facing the permanent magnet of the bottle drive unit, so that the rotating body was driven by the rotating plate by the magnetic force between the permanent magnets.

<Operation> Fluid such as water stored in the container of the bottle body is activated by the action of the magnetic field from the permanent magnet. Now, when the bottle body is placed on the bottle support surface of the bottle drive unit and the motor is driven, the rotating body is driven by the repulsive or attractive force between the permanent magnet on the bottle body side and the permanent magnet on the bottle drive unit side. As a result, the magnetic field also rotates, further promoting activation of the fluid. In this case, the magnetic field from the permanent magnet that functions to drive the rotating body also acts on the fluid inside the bottle body and activates the fluid, so the same permanent magnet can effectively function for both magnetization and drive. This allows effective use of the magnetic field.

<Embodiment> FIG. 1 shows a magnetization processing apparatus according to an embodiment of this invention, which is constructed by combining a bottle main body A and a bottle drive section B. Of these, the bottle body A is for magnetizing the water filled inside the container 1 using a permanent magnet, and the bottle drive section B is for rotating the permanent magnet to rotate the magnetic field. be.

As shown in FIG. 2, the bottle drive unit B has a bottle support surface 71 for supporting the bottom surface of the bottle body A on the top surface of a case 7 made of synthetic resin. A flat DC motor 8 as a drive source is housed therein. This DC motor 8 is fixed on a metal bottom plate 72 screwed to the bottom opening of the case 7, and an aluminum rotary plate 82 is attached to its output shaft 81 parallel to the bottle support surface 71. Two permanent magnets 9 are mounted on the upper surface of the rotating plate 82 via a ferromagnetic plate 83
9 are arranged diagonally. In this embodiment, each permanent magnet 9 has its N magnetic pole located on the side of the bottle support surface 71, and the repulsive force between this permanent magnet 9 and a permanent magnet 44 inside the bottle body A, which will be described later, is used. The rotating body 4 is driven by the rotating plate 82.

A socket 84 electrically connected to the DC motor 8 is attached to the side surface of the case 7. A plug 86 at the tip of a cord wire 85 is inserted into this socket 84, an AC-DC converter 87 at the other end of this cord wire 85 is connected to an AC power source, and a power switch 88 is connected.
When the voltage is turned on, DC voltage is supplied to the DC motor 8. Further, in the case of this embodiment, a bottle sensor 89 consisting of a photomicro switch or the like is provided on the top surface of the case 7, and when this bottle sensor 89 detects that the bottle main body A is set on the bottle support surface 71, , DC motor 8
It is possible to supply power to. Therefore, the bottle body A
is not set on the bottle support surface 71, even if the power switch 88 is turned on, the DC motor 8
is not driven.

Next, as shown in FIGS. 3 and 4, the bottle main body A consists of a container 1 with a spout 3 attached to a spout 21, and a cylindrical shape vertically installed rotatably in the center of the container 1. The rotary body 4 is provided with a manual operation part 6 for manually rotating the cylinder axis of the rotary body 4 connected to the rotary body 4, and an appropriate vertical space is provided inside the rotary body 4. A plurality of permanent magnets 42 and 44 are arranged, and a rotating body 4
A stirring means 5 is provided on the cylindrical wall.

The container 1 has a lid plate 2 having a spout 21 attached to the upper end of a cylindrical main body 11 with an appropriate depth and an upper opening, and a spout 3 provided on the spout 21. It is constructed by covering it with a cap 10.

The cover plate 2 is a molded body made of a synthetic resin material with good lubricity, and a support wall 22 for supporting the rotating body 4 is integrally formed on the inner surface. In this embodiment, as shown in FIGS. 7 and 8, the spout 2 is
Flanges 2 are provided at the upper and lower parts of the cylindrical portion 23 surrounding the cylindrical portion 23.
31, 232 are provided to form two engagement grooves 233, 23.
4, and both flanges 231, 232 have notches 235, 236 formed at equiangular positions around the periphery, the lower engagement groove 234 is for fixing the spout when sealing, and the upper engagement groove Reference numeral 233 is for guiding the rotation of the spout 3.

As shown in FIGS. 3 to 6, the spout 3 is formed into a cap shape with a lower opening that fits the cylindrical portion 23 of the lid plate 2 by molding a synthetic resin material.
The upper end of the support shaft 32 is attached to the lower surface of 1 by insert molding, and the rubber stopper 33 is fitted,
The plug body 33 is adhesively fixed to the lower surface of the top plate 31.

The inner surface of the cylindrical portion 34 of the spout 3 has the cylindrical portion 23 of the lid plate 2.
Convex portions 341, 3 that match the spacing between the upper and lower engaging grooves 233, 234 and fit the notches 235, 236.
42 protrude at equiangular positions around the periphery, and a plate 36 that is supported by an elastic spring 35 and is movable up and down is provided between the plug body 33 and the cylindrical portion 34. This plate 36 has its lower end aligned with the lower side of the upper convex portion 341, and the lower convex portion 342 is aligned with the lower side of the notch 235.
When the plate 36 is engaged with the engagement groove 233
is supported on the upper end surface of the cylindrical portion 23, and the spout 3 including the support shaft 32 can be rotated by the handle 61.
Also, the plate 36 is pressed against the spring force, and both the convex parts 341 and 342 are cut into the notches 235 and 23, respectively.
When the stopper 3 is engaged with the engagement grooves 233 and 234 from the stopper 6, the stopper 3 fits into the spout 21 and is tightly closed.

Further, in this embodiment, the rotating body 4 and the cover plate 2 are connected by a spring 62 to improve the stability of rotation of the cylinder axis of the rotating body 4.

The rotating body 4 is a press-molded body made by pressing a mixture of Bakhanite powder, a binder, and a synthetic resin material at a predetermined temperature, and the entire surface of the rotating body 4 forms a porous wall and has water permeability. It has the effect of adsorbing and filtering impurities in water. Caps 46 and 41 molded from a synthetic resin material with good lubricity are fitted into the upper and lower parts of the rotating body 4, respectively, and the upper cap 46 is supported by the support wall 22 of the cover plate 2.
Further, the lower cap 41 is supported in point contact with the bottom surface of the cylindrical main body 11, and is freely rotatable.
The upper cap 46 has a square hole 47 formed in the center and a slit hole 48 around the square hole.

Each permanent magnet 42, 44 arranged in the rotating body 4
Two permanent magnets are each enclosed in a synthetic resin housing 43 of an arbitrary shape that fits the inner hole of the rotating body 4, and each permanent magnet is supported at appropriate intervals with a cylindrical retainer 45 interposed between the housings 43. has been done.
Each permanent magnet 42 except for the lowest stage has its N and S magnetic poles oriented in the radial direction.
44 has both permanent magnets 44 with the N magnetic pole facing downward;
The distance between the magnets 44 and the permanent magnets 9, 9 of the bottle drive unit B is set appropriately.

The stirring means 5 includes a plurality of blades 51 disposed at a lower position of the rotating body 4, and the water inside the container 1 is stirred by the rotation of the rotating body 4.

A manual operation unit 6 for manually rotating the rotating body 4 engages and links the lower end of the support shaft 32 that supports the plug body 33 with a square hole 47 formed in the cap 46 of the rotating body 4, and also An operating handle 61 is attached at a suitable position on the upper surface of the handle 31.

By filling the container 1 with water, the water passes through the porous wall of the rotating body 4 and is stored in the inner and outer housing portions of the rotating body 4. In this state, the rotating body 4 adsorbs and filters bad odors and other impurities contained in the water by the adsorption action of the porous walls and the action of Bakhan stone, and the permanent magnets 42, 44
applies a magnetic field to the surrounding water, activating the water and increasing the concentration of oxygen ions in the water.

Prior to drinking, the rotating body 4 is rotated about its cylindrical axis using the bottle drive unit B or by manually operating the handle 61.

In this embodiment, when the lower protrusion 342 is engaged with the engagement groove 233 through the notch 235,
A plate 36 is supported on the upper end surface of the cylindrical portion 23, and the spout 3, the support shaft 32, and the rotating body 4 can be rotated by operating the handle. Also, both convex portions 341, 3
42 into the respective engagement grooves 233, 234 and rotate in one direction, it is possible to maintain a sealed seal.
When passing through the plug and removing it upward, the spout 3 including the support shaft 32
can be removed in its entirety.

Now, after removing the spout 3 from the bottle body A,
When this is placed on the bottle support surface 71 of the bottle drive section B and the power switch 88 is turned on, the DC motor 8 of the bottle drive section B is driven and the permanent magnets 9, 9 rotate together with the rotating body 82. Since these permanent magnets 9, 9 and the permanent magnets 44, 44 on the side of the bottle body A have their N magnetic poles facing each other, the rotating body 4 is synchronized with the rotation of the DC motor 8 due to the repulsive force between the permanent magnets. and rotate. As a result, the stirring means 5
stirs the water to replenish oxygen into the water, and the rotation of the permanent magnet 42 rotates the magnetic field acting on the water, further promoting the activation of the water and further increasing the oxygen ion concentration. You can obtain magnetized water that is good for your health. In addition, in this case, the magnetic field by the permanent magnet 44 of the bottle body A that functions to drive the rotary body 4 and the magnetic field by the permanent magnet 9 of the bottle drive unit B act on the water in the bottle body A to activate it.
Efforts are being made to effectively utilize the magnetic field.

Although the above embodiment is used to improve the quality of drinking water, the magnetization treatment device of this invention is not limited to this, and can also be applied to improve the quality of oil and other fluids.

<Effects of the invention> As described above, this invention places the bottle body on the bottle supporting surface of the bottle drive unit and drives the motor, thereby reducing the gap between the permanent magnet on the bottle body side and the permanent magnet on the bottle drive unit side. Since the rotating body is driven by the repulsive or attractive force, the magnetic field of the permanent magnet can be rotated within the fluid, and activation of the fluid is significantly promoted. In addition, the magnetic field produced by the permanent magnet that functions to drive the rotating body acts on the fluid inside the bottle body and also functions to activate the fluid, so the same permanent magnet can effectively function for both magnetization processing and driving purposes. It achieves the purpose of its invention and achieves remarkable effects, such as making effective use of the magnetic field.

[Brief explanation of the drawing]

Fig. 1 is a front view of a magnetization processing device according to an embodiment of this invention, Fig. 2 is a longitudinal sectional view of the bottle drive section, Fig. 3 is a longitudinal sectional view of the bottle main body, and Fig. 4 is a sealing plug of the bottle main body. A vertical sectional view showing the state, FIG. 5 is a bottom view of the spout, and FIG. 6 is a sectional view taken along the line in FIG. 5.
FIG. 7 is a longitudinal sectional view of the lid plate, and FIG. 8 is a perspective view of the bottle body showing how the spout is attached and removed. A...Bottle body, B...Bottle drive unit, 1...
...Container, 4...Rotating body, 21...Spout, 7...
Case, 42, 44... Permanent magnet, 8... DC motor, 71... Bottle support surface, 82... Rotating plate, 8
1...Output shaft, 9...Permanent magnet.

Claims (1)

[Claims for Utility Model Registration] A bottle body comprising a container having a spout and a rotary body equipped with a plurality of permanent magnets rotatably supported, and a bottle body for supporting the bottom surface of the bottle body on the top surface of the case. The bottle drive section has a bottle support surface and a motor as a drive source is housed inside the case, and the bottle drive section has a rotary plate on the output shaft of the motor and a bottle support surface. A plurality of permanent magnets are installed in parallel to each other at predetermined angular positions on the upper surface of the rotating plate, and a permanent magnet is positioned at a lower position of the rotating body inside the bottle body to face the permanent magnet of the bottle drive unit. A magnetization processing device in which a rotating body is driven by a rotating plate using magnetic force between permanent magnets. 2. The magnetization processing apparatus according to claim 1, wherein the rotating body is constructed by disposing a plurality of permanent magnets at appropriate intervals inside a filter cylinder provided with stirring means. The magnetization processing apparatus according to claim 1 or 2, wherein the rotating body is connected to a manual operation handle.