JP2010036166A - Magnetic activator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a magnetic activator for increasing a magnetic treatment effect by performing fluid treatment twice or more at a stroke only across a pair of magnets. <P>SOLUTION: In the magnetic activator, a tube member 3 held between magnetic treatment parts having the relative magnets arranged to yokes 1 is arranged to revolve between the magnetic treatment parts and the outside of the yokes 1 twice or more to pass the fluid in the tube member 3 through a ferromagnetic field part a large number of times containing twice. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

The present invention relates to a magnetic processing apparatus, and more particularly to a magnetic processing apparatus and a pipe body that magnetically improve and purify the quality of liquids such as fuel, drinking water, industrial water, waste water, and agricultural water.
The present invention

There are many examples in which a tube sandwiched between relative magnetic processing units having magnets arranged in a yoke has been conventionally designed for only one-time treatment. For example, a magnet arranged in a yoke according to Japanese Patent Application No. 2005-500141. It is clear that the fluid activation effect is certainly recognized by the tube sandwiched between the relative magnetic processing units having, but the effect is almost doubled when the same two are doubled.
Japanese Patent Application No. 2005-500141

Some magnetic processing apparatuses that perform such magnetic processing have a structure in which a magnet is arranged so as to sandwich a liquid tube.
If the magnetic flux leaks to the outside, the precision of the precision equipment will be lost, causing noise to the electronic equipment and causing other problems. While preventing the leakage of magnetic flux from becoming a defect such as noise to electronic equipment.
This is a magnetic processing device and a tubular device that increase the magnetic processing effect by making it possible to perform two or more processings at once by seeing more effectively between a pair of magnets.

The present invention provides a magnetic activation device in which a tubular body is arranged in a spiral shape so that the fluid in the tube passes through the strong magnetic field portion twice or more times by turning around the magnetic processing portion and the outside of the yoke.

Enhancing the magnetic treatment effect by allowing two or more fluid treatments to be performed at a stroke between a pair of magnets.

In a magnetic processing apparatus in which magnetic processing units having magnets with yokes are arranged opposite to each other across the flow path, the magnet is disposed on the flow path side of the yoke and the surfaces of the SN different magnetic poles pass through the flow path. The yoke is formed so that the side surfaces of the yoke are opposed to each other across the flow path and are larger than the opposed surface of the magnet, and the liquid tube sandwiched between the SN different magnetic poles is a liquid. The cross section of the swivel portion between the inlet and the yoke that is not sandwiched between the different magnetic poles and the swivel outlet is larger than the portion sandwiched between the SN different magnetic poles to form a loop with reduced fluid pressure loss.
The liquid tube crossing the strong magnetic field lines sandwiched between the SN different magnetic poles has two or more at the part sandwiched between the SN different magnetic poles, and the fluid cuts the magnetic flux twice or more with a pair of magnets, activating the liquid, burning power It is characterized by a magnet, a yoke, and a spiral tube having a different cross-section that can be further improved than the penetration power, the dissolution power, and the like.

Some magnetic processing apparatuses that perform such magnetic processing have a structure in which a magnet is arranged so as to sandwich a liquid tube.
If the magnetic flux leaks to the outside, the precision of the precision equipment will be lost, causing noise to the electronic equipment and causing other problems. The magnetic flux leakage becomes a defect such as noise to the electronic equipment.
In a magnetic processing apparatus in which magnetic processing units having magnets with yokes are arranged opposite to each other across the flow path, the magnet is disposed on the flow path side of the yoke and the surfaces of the SN different magnetic poles pass through the flow path. The yoke is formed so that the side surfaces of the yoke are opposed to each other across the flow path and are larger than the opposed surface of the magnet, and the liquid tube sandwiched between the SN different magnetic poles is a liquid. The cross section of the swivel portion between the inlet and the yoke that is not sandwiched between the different magnetic poles and the swivel outlet is larger than the portion sandwiched between the SN different magnetic poles to form a loop with reduced fluid pressure loss.
The liquid tube crossing the strong magnetic field lines sandwiched between the SN different magnetic poles has two or more at the part sandwiched between the SN different magnetic poles, and the fluid cuts the magnetic flux twice or more with a pair of magnets, activating the liquid, burning power It is characterized by a magnet, a yoke, and a spiral tube having a different cross-section that can be further improved than the penetration power, the dissolution power, and the like.

The tube sandwiched between the magnetic processing units having the relative magnets disposed on the yoke swirls between the magnetic processing unit and the outside of the yoke more than once so that the fluid in the tube passes through the strong magnetic field unit including many times. The activation side of the liquid is improved by several steps from the one-time processing by the magnetic activation device arranged on the feeding side, while the tube passes through the magnetic processing unit having a narrow relative magnet many times including two times. At the same time as the booster pump, after passing through the magnetic processing section on the outlet side, it will not be able to withstand fluctuations in the working load of the fluid and the engine etc. will stop easily. Great effect.
If the distance between the NS of the magnets is increased due to the tubular body, the magnetic flux density will be inferior, and the narrower one can increase the magnetic flux density. Therefore, in order to prevent fluid pressure loss, the tubular body sandwiched between the magnetic processing parts Spiral tubular body with small cross-sectional area, fluid inlet / outlet and swirling tubular part thick and large cross-sectional area with a tubular cross-sectional area difference that makes it easy to keep the magnetic flux density of the tubular part at the center of the relative magnet high

As shown in FIG. 1, on the inner side of the yoke 1, the facing magnet 2 N pole side and the S pole side are arranged at a distance sandwiching the tube. Accordingly, a substantially uniform magnetic field is formed, and the fluid passing through the tube 3 disposed in the gap is exposed to the substantially uniform magnetic field. FIG. Because of the tubular body, the same fluid is subjected to the substantially uniform magnetic field twice and receives more magnetic action than once.
Similarly, FIG. 3 shows the distance between the opposing SNs in order to maintain a stronger magnetic field sandwiched between different SN magnetic poles, where the same fluid is applied four times with a pair of magnets 2 and the degree of activation is improved. Is smaller or better, and the tube 3 has a flat oval shape rather than a circle, and if the distance is reduced, fluid pressure loss is likely to occur. To compensate for this, the cross-sectional area of the swivel tube surrounding the yoke is placed in the SN gap. If the tube cross-sectional area is made larger, the pressure loss is reduced.
FIG. 5 shows an elastic tube portion provided on the fluid outlet side. The tube body 13 has an elastic portion 11 and can absorb pressure fluctuations on the fluid outlet side. Thereby, the fluctuation | variation by the accelerator of a motor vehicle can be relieved, for example.

  The present invention relates to a magnetic processing apparatus, and more particularly to a magnetic processing apparatus and a tube that magnetically improve and purify the quality of liquids such as fuel, drinking water, industrial water, waste water, and agricultural water.

Illustration of relationship between magnet and yoke An explanatory diagram in which a magnetic field is generated twice by a swivel tube surrounding a yoke, sandwiched between different SN magnetic poles. A cross-sectional view of the entire two elliptical tubes sandwiched between different SN magnetic poles and the fluid passing through the magnetic field twice Partial cross-sectional view of four circular pipes with fluid flowing four times between magnetic poles Example of an elastic tube part provided on the fluid outlet side An example of a fluid flowing through a magnetic field three times between different SN magnetic poles

Explanation of symbols

1 Yoke 2 Magnet 3 Tube 11 Tube Exit 13 Elastic Tube

Claims (3)

The tube sandwiched between the magnetic processing units having the relative magnets disposed on the yoke swirls between the magnetic processing unit and the outside of the yoke more than once so that the fluid in the tube passes through the strong magnetic field unit including many times. Magnetic activation device located in A series of pipes having a combination of expansion and contraction parts that can withstand fluctuations in the use load of the fluid after passing through the magnetic processing unit at the outlet side at the same time as the feed-side boost pump for passing the tube many times including two times in the magnetic processing unit having a narrow relative magnet apparatus To prevent fluid pressure loss, the tube part sandwiched between the magnetic processing parts has a small cross-sectional area, and the fluid inlet / outlet and the swiveling pipe part are thick and have a large cross-sectional area, making it easy to keep the magnetic flux density at the center of the relative magnet high. Tube with different cross-sectional area difference