KR100249076B1 - Liquid magnetizer - Google Patents

Abstract

This invention is an improvement of the liquid magnetization apparatus. The present invention encloses a plurality of magnets in a housing and distributes the liquid flow through the gap between the magnets connected to the inlet and the outlet of the housing to magnetize the liquid flow. The magnetic field focusing portion is arranged in the liquid flow passage and the liquid flow passage that constitute the focusing portion of the magnetic field. It is composed of one or more magnets to expose the liquid flow to the concentrated magnetic field, the passage of the liquid flow is connected to the inlet and the outlet, the liquid flow passage is a liquid flow magnetization device characterized in that it comprises a flow rate delay means of the liquid flow. According to the present invention, the flow path of the liquid flow can be limited to a narrow passage where the magnetic field is concentrated, and the magnetic field of the magnet can be concentrated in the limited liquid flow passage to expose the liquid oil to the focused magnetic field, and the liquid flow passage is formed in parallel to delay the flow velocity of the liquid flow. Therefore, the exposure time of the liquid flow to the magnetic field is increased, and the magnet assembly including a plurality of narrow liquid flow passages of the parallel columns is included, so that manufacturing, assembly, and after-sales service are facilitated.

Description

Liquid magnetizer

This invention is an improvement of the liquid magnetization apparatus. The liquid magnetization apparatus is applied to a device that magnetizes drinking water by exposing drinking water such as drinking water, milk, and fruit juice to a magnetic field, and a device that magnetizes fuel oil by exposing fuel such as gasoline and diesel oil to a magnetic field. Such a magnetizer is the same in that the liquid is exposed to a magnetic field and magnetized, but has a difference in its use, field of use, and apparatus. In the present invention, the fuel oil such as gasoline, diesel oil, etc. in drinking water, such as drinking water, milk, fruit juice will be abbreviated as liquid.

Originally, magnetized water refers to natural water that helps mental and physical health and prevents diseases. It was created by the exposure of water flowing through deep mountain valleys and underground veins to the earth's magnetic field in a clean natural environment. However, due to the high industrialization, the contents of harmful substances such as noxious gases and heavy metals in the air and water have increased, making it impossible to obtain high quality magnetized water from the natural environment. As a result, diseases such as chronic fatigue and cold have increased in general, and artificial magnetized water was considered as a drink for health.

The magnetized water device is a device in which the natural magnetized water generation mechanism is mechanically reduced. The magnetized water device is obtained by exposing drinking water such as water, milk and fruit juice in the magnetic field of the permanent magnet. The magnetization phenomenon is known to increase the sensitivity to the Earth's magnetism by magnetizing the water molecules, and the magnetic phenomenon is interfered with the spin of the hydrogen atoms of the constituent elements of the water to purify the nature of the water, but the ultimate phenomenon can be explained. none. Water molecular magnetization theory can explain magnetized water as a healthy water, but cannot explain magnetized oil and the theory of interference of hydrogen atom spin can explain magnetized water and magnetized oil at the same time. do.

The magnetizer for fuel oil is a field of application that extends the experience gained from magnetized water. It is mostly applied to fluid fossil fuels such as diesel, gasoline, jet oil and hydraulic oil. This magnetization oil device is also obtained by exposing fluid to the magnetic field of the permanent magnet in the same way as the magnetization water device. Magnetization oil has a sticky and slippery property, transparency is increased, combustion is smooth, engine corrosion is reduced, and exhaust gas is toxic. The effects of various fields, such as weakening and increasing calories, are empirically transmitted. The practical magnetization oil system is a large diesel oil magnetizer used for the fuel oil magnetization of ship propulsion engines, a small fuel oil magnetizer is commercialized as a gasoline or diesel oil magnetizer of automobiles. It is widely used in ships and motor vehicle engines in various regions leading the preservation of the natural environment such as the United States, Australia and Europe.

In this way, the apparatus for magnetizing water and fuel oil in common is abbreviated as liquid magnetization apparatus in this invention.

Conventional liquid magnetizers include patent publication 95-7049 magnetized water generating connector for water supply pipe, utility model notification 96-9013 magnetization water ring, utility model notification 95-6404 magnetization water purifier, utility model notification 94-475 funnel for magnetization water, public patent publication 91-11283, U.S. Patent No. 5,248,437 and the like are known, and it is recommended to expose the liquid to the magnetic field of 4000 gauss or more for several seconds to several tens of seconds as a magnetization method of the liquid. Also, as a configuration for exposing liquid flow to a magnetic field, one or more disc-shaped magnets are enclosed in a housing and a passage for liquid flow is formed between the magnets, and the south and north poles of adjacent magnets are arranged to face each other, or the N, N, and S poles Arranged to face the S pole is recommended.

However, the above-mentioned liquid magnetizers have a ring-shaped or disc-shaped magnet in the housing and form a liquid passage between the planes of the magnets connected to the inlet and the outlet of the magnet. Dispersed in the circumferential cross section of, the magnetic force was not concentrated and the strength of the magnetic field applied to the liquid flow was relatively weakened.

As another fluid magnetization apparatus, the method of arranging permanent magnets mounted on a pipe of Japanese Patent Laid-Open No. 7-204655 is a technical standard for piping a pipe in a 'U' or 'S' shape between magnetic poles of a continuous array magnet. Presenting. Such an attempt is to improve the magnetization efficiency if the flow path is constructed in the magnetic pole passage, so that the pipe wall of the pipe is arranged between the liquid flow and the long field, which reduces the magnetization efficiency. It can be seen that the specification is suggested.

The object of the present invention is to restrict the flow path of the liquid flow as a narrow passage, to focus the magnetic field of the magnet in the narrow liquid passage to directly expose the liquid oil to the focused magnetic field passage, and to expose the exposure time of the liquid flow to the magnetic field focused in the housing. It is an object of the present invention to propose a magnet assembly for delaying the flow rate of liquid flow so as to lengthen it and to easily form a parallel narrow flow passage for delaying the flow rate of liquid flow.

1 is a conceptual diagram of the apparatus focusing magnetic field passage of the present invention.

2 is a cross-sectional view of an embodiment of the present invention device.

3 is a cross-sectional view taken along line A-A of FIG.

4 is a cross-sectional view taken along line B-B in FIG.

5 is a cross-sectional view taken along line C-C of FIG.

* Explanation of symbols for main parts of the drawings

1: liquid 2: passage

3: magnet 31: magnetic field focusing unit

4 housing 5 magnet assembly

43, 44: Information space

The present invention will be described in detail with reference to the accompanying drawings.

In the magnetic field of the 'I' type 'U' or 'S' type to form a magnetic field is provided by continuously matching the magnetic poles of the permanent magnet in the housing, and by connecting the fluid inlet and outlet to the passage to which the magnetic field is applied, It consists of a narrow flow passage configured to pass through the concentrating portion of the magnetic field and one or more magnets arranged to expose the liquid flow directly to the focused magnetic field by arranging the magnetic field focusing portion in the liquid flow passage. The passage of the liquid flow is connected to the inlet and the outlet. It is a liquid magnetization apparatus characterized by comprising a flow rate delay means.

In Fig. 1, the concept of the liquid flow magnetization device of the present invention is simply expressed. When comparing the features of the present invention shown in FIG. 1 to the arrangement of permanent magnets mounted on a pipe, the Japanese Laid-Open Patent Publication No. 7-204655, the permanent magnets of the present invention are configured to focus magnetic poles and the liquid flow to attenuate the magnetic field. It is exposed directly to the focused magnetic field without going through layers.

Specifically, FIG. 1 shows a configuration of a narrow passage 2 for introducing a liquid flow 1 and a magnet 3 arranged to focus a magnetic field in the passage 2. In FIG. 1, the passage 2 of the liquid flow 1 is transparent to the magnetic field so that the concentrated magnetic field of the permanent magnet is directly applied to the liquid flow without being subjected to magnetic field attenuation, such as a pipe wall of a pipe. By connecting the passage 2 transparent to the inlet 21 and the outlet 22 with respect to the magnetic field in this way, the liquid flow 1 forms the focused magnetic field passage 2 formed by continuously matching the focusing portions 31 of the magnet 3. To pass. That is, the arrangement of the magnets 3 is arranged such that the magnetic field focusing portions 31 of the magnets x1, x2, x3, and xn (shown up to x3 in FIG. 1 only) face each other in a narrow passage. The magnetic field focusing portions 31 of the two magnets facing each other are arranged so that the focusing portions of adjacent magnets face each other when the polarities are different from each other, or that both ends of one magnet face each other and the focusing portions of the adjacent magnets face each other when the polarities are the same. The magnets 3 arranged to face the magnetic field focusing part 31 stack one or more magnets 3 as y1, y2, y3, y4, yn. The polarity arrangement of the laminated magnets y, 1 y2, y3, y4, yn can be in various combinations as shown in Tables 1, 2, and 3.

TABLE 1

When arrays of stimuli are attracted to each other.

TABLE 2

When the magnetic poles are arranged in pairs.

TABLE 3

When the mutually attracting stimulus and the pushing stimulus are arranged in alternating pairs.

As shown in Table 1, Table 2 and Table 3, the liquid flows through the narrow passage 2 is magnetized by being exposed to the concentrated magnetic field, and in particular, the liquid flow is exposed between the focused magnetic fields drawn from each other in Table 1 and pushes each other in Table 2. Liquid flow is exposed between the concentrated magnetic fields, and in FIG. 3, the liquid flow is magnetized by continuously exposing the liquid flows to a magnetic field that pulls each other and a magnetic field that pushes each other.

2 is an embodiment to which the inventive concept of FIG. 1 is applied.

The magnet assembly 5 was embedded in the housing 4 and sealed with a lid 41. A liquid flow passage (2) which directly imparts a focused magnetic field to the liquid flow with a 5 mm gap w1 between the magnetic field focusing portions 31 at both ends of the magnet 3 in the housing 4 and a 5 mm gap w2 between the magnet support 51. To form a plurality. Therefore, the liquid flows through the passage formed by the combination of the two gaps w1 and w2, and the magnetic field directly imparts a focused magnetic field to the liquid flow. A circulation space 40 is formed at the bottom of the magnet assembly 5 of the housing 4. When a part of the passages 2 is connected to the liquid inlet and the other part of the passages 2 is connected to the outlet, the bottom liquid flow circulating space 40 connects the inlet passage 2 and the outlet side passage, Promote a turn. In FIG. 2, FIG. 4, and FIG. 5, the two guide space portions 43 and 44 formed on the magnet assembly 5 partitioned by the diaphragms 42 are formed inside the cover 41 of the housing. The inlet 21 and the outlet 22 formed at, 46 are connected to the mist space portions 43 and 44 through the holes 47 and 48, respectively. Therefore, the plurality of liquid flow passages 2 arranged in the magnet assembly 5 are divided into diaphragms 42 when embedded in the housing 4, and part of the liquid flow passages 2 are connected to the inlet 21 through the guide space 43. The inflow path of the remaining part is connected to the outlet 22 via the guide space 44 to form a discharge path of the liquid flow. That is, the liquid flow is the inlet 21, the hole 47, the guide space portion 43, the inlet parallel liquid flow passages 2, the circulation space portion 40, the liquid flow passages 2 of the outlet side parallel, guide It flows through the space 44, the hole 48, and the outlet 22. In the flow path of the liquid flow, the inlet-side guide space portion 43 connects one inlet 21 to the plurality of passages 2, and the outlet-side guide space portion 44 connects the plurality of passages 2 to one outlet. Since it is connected to (22), the inlet and the outlet are respectively connected to the parallel passage. In the circulating space portion 40 in the flow path of the liquid flow, impurities are used as deposition portions.

2 and 3, the magnet assembly 5 embedded in the housing 4 is configured by arranging and supporting the magnets 3 on the support 51 so as to form the liquid flow passage 2. The arrangement of the magnets 3 arranges one or more magnets 3 in one or more circumferential tracks received in the housing 4. The magnet support 51 is made of a magnetic induction material that concentrates synthetic resin, synthetic rubber, or magnetic field with low magnetic resistance in the passage 2.

As such, the present invention creates a narrow liquid flow passage concentrating the magnetic field, and directs the liquid flow to the focused magnetic field in the passage provided with the focused magnetic field, and magnetizes the liquid flow passage in parallel to speed up the flow velocity of the liquid flow. The present invention is to provide a magnet assembly for forming a plurality of high efficiency liquid magnetization apparatus and to facilitate the manufacture, assembly and after-sales service.

Claims (2)

In the magnetic field of the 'I' type 'U' or 'S' type to form a magnetic field is provided by continuously matching the magnetic poles of the permanent magnet in the housing, and by connecting the fluid inlet and outlet to the passage to which the magnetic field is applied, A plurality of liquid flow passages 2 are provided in the housing 4 to directly impart a focused magnetic field to the liquid flow by the gap w1 between the magnetic field focusing portions 31 at both ends of the magnet 3 and the magnet support 51. In addition, a liquid flow circulation space portion 40 is formed at the bottom of the housing 4, two guide space portions 43 and 44 partitioned by diaphragms 42 are formed inside the cover 41 of the housing, and two guides are provided. The spaces 43 and 44 are connected to the inlet 21 and the outlet 22, respectively, so that some of the parallel passages 2 commonly connected in the bottom circulation space 40 are connected to the inlet 21, Liquid flow magnetization device, characterized in that configured to be connected to the outlet (22). 2. A liquid magnetization apparatus according to claim 1, characterized in that the arrangement of the magnets (3) is arranged in one or more magnets (3) on one or more circumferential tracks received in the housing (4).

Images