TWI567767B - Fluid magnetizer with flexible assembly and flexible assembly method thereof - Google Patents

Description

Elastically assembled fluid magnetizer and elastic assembly method thereof

The invention relates to an elastically assemblable fluid magnetizer, in particular to at least four magnet assemblies, which can be looped around a hollow tube, and the magnet assembly has two pre-bonding options for ringing in the middle. The empty tube pre-bonded magnet assembly has magnetic attraction or repellent characteristics to facilitate assembly or disassembly of the fluid magnetizer.

When the water passes through a vertical magnetic field of a certain intensity, some associated water molecules connected by hydrogen bonds break, causing the larger water molecule group to be separated into several smaller water molecules, and the smaller water molecules group is permeable to water. Physical properties such as chemical solubility and surface tension are much enhanced. Industrially, a small amount of boiler water is initially treated with a magnetic field to reduce scale. Nowadays, the application range of magnetized water is constantly increasing. For example, chemical industry, agriculture, construction, etc. have applications that use magnetized water to improve the status quo. In recent years, the food and pharmaceutical industry has begun to use magnetized water to improve human health. Fluid magnetizers are also used in the treatment of oil products, including gasoline, diesel, kerosene, etc. Their utility includes increasing the fluidity of oil, inhibiting the reproduction of fungi, improving combustion efficiency, reducing the generation of exhaust gas after combustion, etc. Energy saving and environmental benefits.

Referring to Fig. 1A, there is shown a conventional fluid magnetizer 10 comprising a hollow tube 13 and two magnets 11, 12. The magnetic field generated between the magnets 11 and 12 (see an arrow connected between the magnets 11 and 12 in the drawing) passes through the hollow tube 13 and magnetizes a fluid (for example, water or oil) flowing through the hollow tube 13, and Figure 1B shows the distribution of magnetic field lines (the dotted line shows the magnetic field gradient, magnetic field lines) The magnetic strength of M1 is the highest, which decreases in order. It is known that the magnetic flux leaks out of the hollow tube 13 at a relatively high proportion (for example, magnetic lines of force such as magnetic lines M12 and M13 do not pass through the hollow tube 13). Further, since the magnetic force required for the magnetizing fluid is high, the magnetic strength of the magnets 11, 12 is strong. For example, during maintenance, the operation of unwinding the magnets 11, 12 is difficult due to the strength of magnetic attraction.

How to make the fluid magnetizer easy to assemble or disassemble and increase the proportion of the magnetic field acting on the magnetized fluid by simple and effective design is an important key to the development of the fluid magnetizer.

In one aspect, the present invention provides an elastically assemblable fluid magnetizer that can be disposed about a hollow tube and that includes: at least four magnet assemblies including first, second, third, and fourth magnets The assembly may be combined to form a hollow region for receiving the hollow tube to magnetize the internal fluid as the internal fluid passes through the hollow tube, wherein when combined, the first and fourth magnet assemblies have a magnetic property therebetween a first junction, a first junction between the first and second magnet assemblies, a second junction between the second and third magnet assemblies, and a third junction between the second and third magnet assemblies. There is a fourth junction between the third and fourth magnet assemblies that is magnetically repulsive.

In one embodiment, the magnet assemblies are pre-bonded to the third junction via the first junction to respectively generate at least two pre-bonded magnet assemblies, and the pre-bonded magnet assemblies repel the second junction via magnetic repulsive The assembly and disassembly are performed with the fourth junction.

In another embodiment, the magnet assemblies are pre-bonded to the fourth junction via the second junction to generate at least two pre-bonded magnet assemblies, and the pre-bonded magnet assemblies are magnetically attracted to the first connection. The surface and the third junction are assembled and disassembled.

In one embodiment, each magnet assembly includes: a first direction magnet and a second direction magnet, wherein a magnetic direction of the first direction magnet faces or is away from one of the junctions, and a magnetic direction of the second direction magnet Or facing away from the aforementioned hollow area.

A preferred embodiment of the above embodiment is: the first and fourth magnet assemblies a first direction magnet is adjacent to the first joint surface and opposite in magnetic direction, and the first direction magnets of the second and third magnet assemblies are adjacent to the third joint surface and opposite in magnetic direction, and the first and second magnet assemblies are opposite The second direction magnet is adjacent to the second joint surface and has the same magnetic direction, and the second direction magnets of the third and fourth magnet assemblies are adjacent to the fourth joint surface and have the same magnetic direction; wherein the magnet assembly is the first The directional magnets are preferably identical in structure and can share the same component. The second directional magnets of the first and second magnet assemblies are preferably identical in structure and can share the same component and the second direction of the third and fourth magnet assemblies. The magnets should be identical in structure and share the same parts.

In one embodiment, each of the magnet assemblies may further include a magnet in a second direction between the first direction magnet and the second direction magnet. The magnets in the second direction of the first and second magnet assemblies are preferably identical in structure and can share the same component, and the magnets in the second direction of the third and fourth magnet assemblies are preferably identical in structure and can share the same component. .

In one embodiment, the hollow tube sequentially includes an inlet narrow tube, a magnetized region wide tube, and an outlet narrow tube. The magnet assembly is disposed around the wide tube and the internal fluid is from the inlet narrow tube. Flowing into the hollow tube, flowing through the wide tube of the magnetization zone, flowing out of the hollow tube from the narrow tube of the outlet, or the hollow tube sequentially comprises an inlet tube having the same inner diameter, a magnetized zone tube, and an outlet tube. The magnet assemblies are disposed around the magnetized tube.

In one embodiment, the circumference of the hollow tube includes at least two sets of magnet assemblies according to the direction of the internal fluid, which respectively generate a first-order magnetic circuit region and a second-order magnetic circuit region, wherein the internal fluid is The hollow tube first passes through the first-order magnetic circuit region, and then passes through the second-order magnetic circuit region, and the magnetic strength of the second-order magnetic circuit region is higher than the first-order magnetic circuit region.

In another aspect, the present invention provides a method of elastic assembly of a fluid magnetizer, comprising: providing at least four magnet assemblies, including first, second, third, and fourth magnet assemblies; determining magnetic attraction or magnetic phase The final assembly is performed in a repulsive manner; the magnet assemblies are combined into at least two pre-bonded magnet assemblies, and when the first and fourth magnet assemblies are pre-bonded, there is a magnetically attracted first junction therebetween, when the first When pre-bonding with the second magnet assembly, there is a magnetically repulsive second junction therebetween, when the second and third magnet assemblies are pre-bonded, a third junction having a magnetic attraction, when the third and fourth magnet assemblies are pre-bonded, having a magnetically repulsive fourth junction therebetween, wherein when it is decided to adopt a magnetic repellent manner for final assembly, The step of combining the at least two pre-bonded magnet assemblies is to pre-bond the first and fourth magnet assemblies and pre-bond the second and third magnet assemblies, and when final assembly is determined by magnetic attraction The step of combining the at least two pre-bonded magnet assemblies is to pre-bond the first and second magnet assemblies and pre-bond the third and fourth magnet assemblies; and assembling the pre-bonded magnet assemblies in one Around the empty tube.

The elastic assembly method of the fluid magnetizer may further include: disassembling the second junction between the first and second magnet assemblies and/or disassembling the fourth junction between the third and fourth magnet assemblies to Repair or replace.

The purpose, technical content, features and effects achieved by the present invention will be more readily understood by the detailed description of the embodiments.

10‧‧‧Legacy Fluid Magnetizer

11, 12‧‧‧ magnet

13‧‧‧ hollow tube

20, 30‧‧‧ Fluid Magnetizer

21, 22, 23, 24‧‧‧ magnet assemblies

211, 222, 232, 241‧‧‧ first direction magnet

212, 221, 231, 242‧‧‧ second direction magnet

213, 223, 233, 243‧ ‧ inner magnet

25‧‧‧ hollow tube

251‧‧‧ inlet narrow tube

252‧‧‧Magnetic area wide tube

253‧‧‧Export narrow tube

254‧‧‧ entrance tube

255‧‧‧Magnetic area tube

256‧‧‧Export tube

A1, A2‧‧‧ direction

F21, F22, F23, F24‧‧‧ pre-bonded magnet assembly

M1, M12, M13, M2, M21, M22, M3‧‧‧ magnetic lines

MS1‧‧‧first-order magnetic circuit area

MS2‧‧‧second-order magnetic circuit area

R1‧‧‧First Magnetic Circuit Area

R2‧‧‧Second magnetic circuit area

S, N‧‧‧ magnetic pole

S1‧‧‧ first junction

S2‧‧‧ second junction

S3‧‧‧ third junction

S4‧‧‧ fourth junction

ST1~ST6‧‧‧Steps

Figure 1A shows a conventional fluid magnetizer.

Figure 1B shows the magnetic gradient distribution of a conventional fluid magnetizer of Figure 1A.

2A and 2B are diagrams showing two sets of assembly and disassembly of the elastically assemblable fluid magnetizer according to an embodiment of the present invention.

Figure 2C shows the magnetic gradient distribution of the fluid magnetizer according to Figs. 2A, 2B.

Figure 3A shows an elastically assembled fluid magnetizer in accordance with another embodiment of the present invention.

Figure 3B shows the magnetic gradient distribution of the fluid magnetizer according to Figure 3A.

Figure 4 shows a hollow tube design in accordance with an embodiment of the present invention.

Fig. 5 shows two sets of magnet assemblies provided in a hollow tube in accordance with an embodiment of the present invention.

Figure 6 is a flow chart showing the method of elastic assembly of a fluid magnetizer in accordance with an embodiment of the present invention.

The above and other technical contents, features and advantages of the present invention will be apparent from the following detailed description of the preferred embodiments. The directional terms mentioned in the following embodiments, such as up, down, left, right, front or back, etc., are only directions referring to the additional drawings. The drawings in the present invention are intended to be illustrative, and are intended to represent the functional relationship between the various components and the components. The shapes, thicknesses, and widths are not drawn to scale.

Referring to Figures 2A and 2B, there are shown two assembly or disassembly schematics of an elastically assembleable fluid magnetizer 20 in accordance with one aspect of the present invention. The fluid magnetizer 20 comprises: four magnet assemblies 21, 22, 23, 24, respectively comprising a minimum of two magnets (for example, the magnet assembly 21 comprises magnets 211, 212, please refer to the following description for details), the magnet assemblies 21, 22, 23 Between 24 and 24, a first connecting surface S1, a second connecting surface S2, a third connecting surface S3, and a fourth connecting surface S4 are respectively connected to form a hollow region, and the hollow region can be set a hollow tube 25 for magnetizing an internal fluid (not shown) in the hollow tube 25, the internal fluid being not limited to water, but also other fluids having a molecular polarity (or magnetizable fluid), such as: gasoline, diesel Etc., the use of fluid magnetizers due to fluid permeability, chemical solubility and surface tension and other physical properties are enhanced, the engine operating efficiency is improved, and has a fuel-saving effect. Tubing transportation, etc., can also improve the transportation efficiency due to the reduced viscosity of the magnetized oil. In addition, magnetized water can also be used in agriculture and fish farming to improve the quality of culture and increase the value of culture by improving the water quality used in farming. It should be noted that the first junction S1 and the third junction S3 have magnetic attraction characteristics, and the second junction S2 and the fourth junction S4 have magnetic repulsive characteristics.

Referring to FIG. 2A, depending on the construction needs, in one of the construction modes, the magnet assemblies 21, 22, 23, 24 may be pre-bonded via the second joint S2 and the fourth joint S4, respectively, to generate at least two pre-bonds. The combination of the magnet assemblies F21 and F22 is not limited to an adjustable combination of locking, snapping, bolting, and the like. Thus, the pre-bonded magnet assemblies F21 and F22 are magnetically coupled. The first junction S1 and the third junction S3 of the suction are assembled or disassembled (assembled or disassembled according to the direction A1), and the advantage is that the pre-bonded magnet assemblies F21 and F22 can be operated by the characteristics of magnetic attraction. For example, the pre-bonded magnet assemblies F21 and F22 are first attracted to each other and looped around the hollow tube 25, and the positions of the pre-bonded magnet assemblies F21 and F22 are adjusted and then fixed.

Referring to FIG. 2B, depending on the construction needs, in another construction mode, the magnet assemblies 21, 22, 23, 24 may be previously combined via the first joint S1 and the third joint S3, respectively, to generate at least two pre- In combination with the magnet assemblies F23 and F24, the bonding manner is not limited to an adjustable combination of locking, snapping, bolting, and the like. The pre-bonded magnet assemblies F23 and F24 are assembled or disassembled via the magnetically repulsive second joint S2 and the fourth joint S4 (assembled or disassembled according to the direction A2), and the advantages are that the pre-bonded magnet assemblies F23 and F24 can be Operates with the characteristics of magnetic repulsive. For example, when the fluid magnetizer 20 is to be disassembled, it can be disassembled from the second joint surface S2 and/or the fourth joint surface S4, and the fluid magnetizer 20 can be opened by magnetic repelling to facilitate construction, for example, maintenance. Or replace. In the case where the magnetic strength is high, the problem of difficulty in work due to the strength of magnetic attraction is solved in the prior art.

In addition, the S indicated in the magnet in the figure represents the magnetic south pole, N represents the magnetic north pole, and the arrow indicates the magnetic direction from the south pole to the north pole.

Referring to Fig. 2C, there is shown a magnetic gradient distribution of the fluidly configurable fluid magnetizer 20 assembled according to Figs. 2A, 2B. The magnet assembly 21, 22, 23, 24 has a first magnetic circuit region R1 and a second magnetic circuit region R2. The first magnetic circuit region R1 passes through the first junction S1, and the second magnetic region R2 passes through the third magnetic field. The joint surface S3 (the magnetic force of the magnetic force line M2 in the figure is the highest, decreasing sequentially, the magnetic lines with strong magnetic force pass through the first joint surface S1 and the third joint surface S3, and the magnetic lines M21 and M22 with lower magnetic force are distributed on the outer side. ). In contrast to FIG. 1B, the loop of the high-strength magnetic lines of the fluid magnetizer 20 passes through the hollow tube 25. The first magnetic circuit region R1 and the second magnetic circuit region R2 can each be regarded as a closed magnetic circuit region, wherein the high-strength magnetic lines are located in the first magnetic circuit region R1 and the second magnetic circuit region R2, and are hollow. The magnetic strength of the tube is up to 95% or more of the magnetic force generated by the integral magnet assembly, and its performance far exceeds that of the conventional fluid magnetizer 10 of FIG.

The magnets inside the magnet assemblies 21, 22, 23, and 24 can be arranged in various ways (refer to Figs. 2A, 2B, and 3A), and it is only necessary to achieve the above-mentioned magnetic attraction characteristics of the first junction S1 and the third junction S3. The second junction S2 and the fourth junction S4 are magnetically repellent, which is in line with the primary object of the present invention. Figure 2A shows one of the magnet arrangements. In this embodiment, each of the magnet assemblies includes a first direction magnet and a second direction magnet. The first direction magnet means that the magnetic direction from the south pole to the north pole is toward or away from one of the joint faces (that is, the magnetic direction line extending from the south pole to the north pole passes through one of the joint faces), and the second direction magnet refers to The magnetic direction from the south pole to the north pole is toward or away from the aforementioned hollow region (that is, the magnetic direction line extending from the south pole to the north pole passes through the aforementioned hollow region).

In detail, in the embodiment, the magnet assembly 21 includes a first direction magnet 211 and a second direction magnet 212. The magnet assembly 22 includes a second direction magnet 221 and a first direction magnet 222. The magnet assembly 23 includes A second direction magnet 231 and a first direction magnet 232, the magnet assembly 24 includes a first direction magnet 241 and a second direction magnet 242.

The first direction magnets 211 and 241 are in close contact with the first joint surface S1, and the first direction magnets 222 and 232 are adjacent to the third joint surface S3, and the first joint surface S1 and the third joint surface S3 are magnetically attracted. The second direction magnets 212 and 221 are adjacent to the second joint surface S2, and the second direction magnets 231 and 242 are adjacent to the fourth joint surface S4, and the second joint surface S2 and the fourth joint surface S4 are magnetically repelled.

Referring to FIG. 2C, the second direction magnet 212 of the magnet assembly 21 and the first direction magnet 211, the first direction magnet 241 and the second direction magnet 242 of the adjacent other magnet assembly 24 generate the first magnetic circuit region R1. The second direction magnet 221 and the first direction magnet 222 of the same magnet assembly 22, the first direction magnet 232 and the second direction magnet 231 of the adjacent other magnet assembly 23 generate the second magnetic path region R2.

It should be noted that the first direction magnets 211, 222, 232, 241 can use the same parts (the first direction magnets 211 and 241 are the same, and the first direction magnets 222 and 232 can be the same as the first direction magnets 211 and 241). Parts, front and rear reverse mounting). In addition, The same components can be used for the second direction magnets 212, 221, and the same components can be used for the second direction magnets 231, 242. Please refer to Figures 2A and 2B.

Referring to FIG. 3A, there is shown a fluid magnetizer 30 of another embodiment. In this embodiment, each of the magnet assemblies may respectively include a second direction inner magnet, for example, the magnet assembly 21 further includes a second direction inner magnet. 213, disposed between the first direction magnet 211 and the second direction magnet 212 of the same magnet assembly; the magnet assembly 24 further includes a second direction inner magnet 243 disposed in the first direction magnet 241 and the second direction of the same magnet assembly Between the magnets 242. The second direction magnet 212 sequentially generates a first magnetic wave between the inner magnet 213 of the magnet assembly 21, the first direction magnet 211, the first direction magnet 241 of the adjacent magnet assembly 24, the inner magnet 243, and the second direction magnet 242. Road area R1 (refer to Figure 3B). The magnet assembly 22 further includes a second direction inner magnet 223 disposed between the first direction magnet 222 and the second direction magnet 221 of the same magnet assembly. The magnet assembly 23 further includes a second direction inner magnet 233 disposed on the same magnet. The first direction magnet 232 of the assembly is between the second direction magnet 231. The second direction magnet 221 sequentially generates a second magnetic circuit with the inner magnet 223 of the magnet assembly 22, the first direction magnet 222, the first direction magnet 232 of the adjacent magnet assembly 23, the inner magnet 233, and the second direction magnet 231. Zone R2 (see Figure 3B).

The fluid magnetizer 30 of FIG. 3A also has elastic-like assembly and disassembly characteristics similar to the fluid magnetizer 20 of FIGS. 2A and 2B, wherein the elastic assembly and disassembly of the magnet assemblies 21, 22, 23, and 24 are flexible. Referring to the description of the previous embodiment, it will not be described in detail herein.

Fig. 3B shows the magnetic gradient distribution of the fluid magnetizer 30 according to Fig. 3A, in which the magnetic force of the magnetic force line M3 is the highest, which is sequentially decreased outward. The loop of the high-strength magnetic field line passes through the first joint S1 and the third joint S3 in a smaller proportion than the embodiment of the second embodiment (for example, the magnetic force line M3 having the highest magnetic strength does not pass through the first joint S1 and the third joint S3) And the ratio of passing through the hollow tube 25 is also lower than that of the embodiment of FIG. 2C (for example, the magnetic force line M3 does not pass through the hollow tube 25), but the effect of the magnetic force concentrated on the hollow tube is still better than that of the first FIG. Fluid magnetizer 10.

Similar to the first direction magnet and the second direction magnet, the inner magnet can also be a common part, and the magnetic direction setting is referred to the drawing.

In the magnet assembly of the foregoing embodiment, a part of the magnet of the magnet assembly may be an electromagnet or a permanent magnet, or a mixture of the two. The purpose is to adjust the strength of the generated magnetic field, such as magnetization for different purposes of the fluid, the required magnetic field strength will be different, which can be used to adjust the strength of the magnetic field.

Fig. 4 shows an embodiment of the invention in which the hollow tube 25 sequentially includes an inlet narrow tube 251, a magnetized region wide tube 252, and an outlet narrow tube 253. A magnet assembly is disposed around the magnetization zone wide tube 252, and the internal fluid flows from the inlet narrow tube 251 into the hollow tube 25, passes through the magnetization zone wide tube 252, and flows out of the hollow tube 25 from the outlet narrow tube 253. The purpose is to reduce the velocity of the internal fluid passing through the magnetized zone wide tube 252 to increase the time to magnetize the internal fluid and enhance the magnetization effect. In another embodiment, referring to FIG. 5, the hollow tube sequentially includes an inlet tube 254 having the same inner diameter, a magnetization tube 255, and an outlet tube 256. A plurality of magnet assemblies are disposed around the magnetization tube 255. The user can decide the required pipe arrangement according to actual needs.

Referring to Figure 5, there is shown an embodiment of the present invention in which the magnet assemblies are arranged in such a manner that the periphery of the hollow tube 25 sequentially comprises at least two sets of magnet assemblies (the 2A, 2B, and 3A drawings are a group of magnet assemblies ( Schematic diagram of the magnet assemblies 21, 22, 23 and 24), the two sets of magnet assemblies represent a magnet assembly other than the one described above, and another set of magnet assemblies are also looped around the hollow tube 25), respectively a first-order magnetic circuit region MS1 (including first and second magnetic circuit regions generated by a group of magnet components) and a second-order magnetic circuit region MS2 (including first and second magnetic circuit regions generated by another set of magnet assemblies) . The internal fluid passes through the first-order magnetic circuit region MS1 in the hollow tube 25, and then passes through the second-order magnetic circuit region MS2. The magnetic component of the magnet assembly of the second-order magnetic circuit region MS2 is higher than the first-order magnetic circuit region MS1. The magnet assembly. The purpose of setting the second-order magnetic circuit region MS2 is to enhance the internal fluid magnetization effect through the first-order magnetic circuit region MS1. The implementation is not limited to the two-order magnetic circuit area, and may be more magnetic circuit areas as needed, depending on the needs.

In one aspect, the present invention provides a method of elastic assembly of a fluid magnetizer. Figure 6 is a flow chart showing the elastic assembly method, comprising: providing at least four magnet assemblies, including first, second, third, and fourth magnet assemblies (step ST1); Or finalizing the assembly in a magnetic repulsive manner (step ST2); combining the magnet assemblies into at least two pre-bonded magnet assemblies, and having a magnetic attraction between the first and fourth magnet assemblies a junction, when the first and second magnet assemblies are pre-bonded, having a magnetically repulsive second junction therebetween, and when the second and third magnet assemblies are pre-bonded, having a magnetic attraction therebetween The three junctions, when the third and fourth magnet assemblies are pre-bonded, have a magnetically repulsive fourth junction therebetween, wherein when the final assembly is decided by magnetic repulsion, the combination is at least two pre- The step of combining the magnet assembly is to pre-bond the first and fourth magnet assemblies and pre-bond the second and third magnet assemblies (step ST3), and when final assembly is decided by magnetic attraction, the combination The step of at least two pre-bonding magnet assemblies pre-bonding the first and second magnet assemblies and pre-bonding the third and fourth magnet assemblies (step ST4); and assembling the pre-bonded magnet assemblies to one Hollow tube Wai (step ST5).

In addition, after assembly, when repair or replacement is required, the second junction between the first and second magnet assemblies and/or the fourth junction between the third and fourth magnet assemblies may be disassembled to Repair or replacement is performed (step ST6). For the relationship and function of each component, refer to the description of the foregoing embodiment.

Compared with the prior art, the magnetic field generated by the fluid magnetizer of the present invention concentrates through the hollow tube, and the magnetization effect of the fluid is much higher than before, and the size of the fluid magnetizer can be reduced due to the concentration of the magnetic field (for example, the magnetic yoke is not required). To guide the magnetic field that overflows the fluid magnetizer). In addition, the magnetic flux leakage generated by the fluid magnetizer of the present invention is very low (see, for example, FIG. 2C). For example, when applied to an automobile engine room, the magnetic field of the overflowing magnetic field has low interference to other circuits in the automobile engine room, and the prior art The fluid magnetizer (for example, Figure 1B) has a high magnetic field ratio. If a car engine room is used, a magnetic field resistance design is required, which causes a lot of trouble. The fluid magnetizer of the present invention can adjust the disassembly and disassembly of the suction or repelling according to the operation requirements, thereby eliminating the need for assembling the jig, and the prior art is required to have the same strength and strong magnetism, and is removed due to the strong magnetic attraction. When the fixture is required to be separated, the present invention is much easier to assemble and disassemble than the prior art. In addition, the magnet in the fluid magnetizer of the present invention can be simplified to an external size (for example, the magnets 211, 212 in FIG. 2A, 221, 222, etc. are all geometrical dimensions), and only need to be magnetized in different directions as needed (for the first magnetization direction, please refer to the direction of the magnets 211, 222, 232, 241 in FIG. 2A, the second charge The magnetic direction refers to the direction of the magnets 212 and 221 in Fig. 2A, and the third magnetization direction refers to the direction of the magnets 231 and 242 in Fig. 2A. Therefore, the requirements for production, parts management, and warehousing procurement are much simpler.

The present invention has been described with reference to the preferred embodiments thereof, and the present invention is not intended to limit the scope of the present invention. For those skilled in the art, various equivalent changes can be immediately considered within the spirit of the invention. Equivalent changes or modifications of the concept and spirit of the invention are intended to be included within the scope of the invention. The invention is not intended to be exhaustive or to limit the scope of the invention. The abstract sections and headings are only used to assist in the search of patent documents and are not intended to limit the scope of the invention.

20‧‧‧ Fluid Magnetizer

21, 22, 23, 24‧‧‧ magnet assemblies

211, 222, 232, 241‧‧‧ first direction magnet

212, 221, 231, 242‧‧‧ second direction magnet

25‧‧‧ hollow tube

A1‧‧ Direction

F21, F22‧‧‧ pre-bonded magnet assembly

S, N‧‧‧ magnetic pole

S1‧‧‧ first junction

S2‧‧‧ second junction

S3‧‧‧ third junction

S4‧‧‧ fourth junction

Claims (12)

An elastically assembled fluid magnetizer for being disposed around a hollow tube, comprising: at least four magnet assemblies including first, second, third and fourth magnet assemblies, which can be combined to form a hollow a region for accommodating the hollow tube to magnetize the internal fluid when the internal fluid passes through the hollow tube, wherein when combined, the first and fourth magnet assemblies have a magnetically attracted first junction, Between the first and second magnet assemblies, a magnetically repulsive second junction, a second magnetic coupling between the second and third magnet assemblies, and between the third and fourth magnet assemblies a magnetic junction repelling the fourth junction; wherein each magnet assembly comprises: a first direction magnet and a second direction magnet, wherein the magnetic direction of the first direction magnet is toward or away from one of the junctions, and the magnet The magnetic direction of the second direction magnet faces or is away from the hollow area, and the first direction magnets of the first and fourth magnet assemblies are adjacent to the first joint surface and the magnetic directions are opposite, and the first and third magnet assemblies are first. Directional magnet The magnets of the first and second magnet assemblies are adjacent to the second joint and have the same magnetic direction, and the magnets of the third and fourth magnet assemblies are adjacent to each other. The fourth junction is the same and the magnetic direction is the same. The elastically assembled fluid magnetizer of claim 1, wherein the magnet assemblies are pre-bonded to the third joint via the first joint to respectively generate at least two pre-bonded magnet assemblies. The pre-bonded magnet assembly is assembled and disassembled by the second joint and the fourth joint that are magnetically repelled. The elastically assemblable fluid magnetizer of claim 1, wherein the magnet assemblies are pre-bonded to the fourth joint via the second joint to generate at least two pre-bonded magnet assemblies. The pre-bonded magnet assembly is assembled and disassembled by the first junction and the third junction via magnetic attraction. The elastically assembled fluid magnetizer of claim 1, wherein the first direction magnets of the magnet assemblies are identical in structure and share the same parts. The elastically assemblable fluid magnetizer of claim 4, wherein the second direction magnet structures of the first and second magnet assemblies are identical to share the same component, and the third and fourth magnets The magnets in the second direction of the assembly are identical in structure and can share the same components. The elastically assemblable fluid magnetizer of claim 1, wherein each magnet assembly further comprises a second direction inner magnet, the first direction magnet and the second direction magnet between. The elastically assemblable fluid magnetizer of claim 6, wherein the first and second magnet assemblies have the same magnet structure in the second direction and share the same component, and the third and fourth The magnets in the second direction of the magnet assembly have the same structure and can share the same components. The elastically assemblable fluid magnetizer of claim 1, wherein the hollow tube comprises an inlet narrow tube, a magnetized region wide tube, and an outlet narrow tube, wherein the magnetized region is surrounded by the wide tube The magnet assemblies are disposed, and the internal fluid flows into the hollow tube from the inlet narrow tube, flows through the magnetization zone wide tube, and flows out of the hollow tube from the outlet narrow tube. The elastically assemblable fluid magnetizer of claim 1, wherein the hollow tube sequentially comprises an inlet tube having the same inner diameter, a magnetized region tube, and an outlet tube surrounded by the magnetized region tube. The magnet assemblies are disposed, and the internal fluid flows from the inlet tube into the hollow tube, flows through the magnetization zone tube, and flows out of the hollow tube from the outlet tube. The elastically assemblable fluid magnetizer of claim 1, wherein the hollow tube comprises at least two sets of magnet assemblies in sequence according to the direction of the internal fluid, which respectively generate a first-order magnetic circuit region And a second-order magnetic circuit region, wherein the internal fluid passes through the first-order magnetic circuit region in the hollow tube, and then passes through the second-order magnetic circuit region, and the magnetic strength of the second-order magnetic circuit region is higher than the The first-order magnetic circuit area. A method of elastic assembly of a fluid magnetizer, comprising: providing at least four magnet assemblies, including first, second, third and fourth magnet assemblies; Deciding to adopt a magnetic attraction or a magnetic repellent manner for final assembly; combining the magnet assemblies into at least two pre-bonded magnet assemblies, and having a magnetic attraction between the first and fourth magnet assemblies when pre-bonded The first junction, when the first and second magnet assemblies are pre-bonded, has a magnetically repulsive second junction therebetween, and when the second and third magnet assemblies are pre-bonded, there is a magnetic attraction therebetween The third junction, when the third and fourth magnet assemblies are pre-bonded, has a magnetically repulsive fourth junction therebetween, wherein the combination is at least two when it is decided to adopt a magnetic repellent manner for final assembly. The step of pre-bonding the magnet assembly is to pre-bond the first and fourth magnet assemblies and pre-bond the second and third magnet assemblies, and when final assembly is determined by magnetic attraction, the combination is at least two The steps of pre-bonding the magnet assembly are to pre-bond the first and second magnet assemblies and pre-bond the third and fourth magnet assemblies; and assemble the pre-bonded magnet assemblies around a hollow tube. The method of elastically assembling a fluid magnetizer according to claim 11, further comprising: disassembling the second junction between the first and second magnet assemblies and/or disassembling the third and fourth magnet assemblies The fourth junction is for repair or replacement.