TWM550300U - Liquid magnetization device - Google Patents

Description

Fluid magnetization device

The present invention relates to a technique for magnetizing a fluid, and more particularly to a fluid magnetization device that enhances a coil induced magnetic field to enhance fluid magnetization.

The magnetized flow system has the characteristics of high permeability, high solubility, low adhesion, and non-deterioration. The user can drink activated cells and maintain the body's weak alkaline constitution.

As shown in Fig. 1, it is a schematic view of a conventional fluid magnetization device. The conventional fluid magnetization device mainly comprises an outer tube 11, an inner tube 12, a water flow tube 13 and a copper coil 14; the inner tube 11 can provide an inner tube 12, and the water tube 13 can be disposed in the inner tube 12. The copper coil 14 is wound around the outer tube 11; when the fluid enters from the water inlet 131 of the water flow tube 13, it can be magnetized by the magnetic field generated by the copper coil 14, so that the fluid flows out of the water outlet 132 of the water flow tube 13. A magnetized fluid can be formed. However, in the conventional fluid magnetization device, the inner tube 12 is provided with a spiral-shaped water flow tube 13 so that the integral magnetization device is formed using an air core, so that the magnetic field strength is too weak, and a good magnetization effect cannot be obtained.

Furthermore, as shown in Fig. 2, it is a schematic view of another conventional fluid magnetization apparatus. The conventional fluid magnetization device mainly comprises an outer tube 21, an inner tube 22 and a plurality of magnets 23; the plurality of magnets 23 are spaced apart from each other on two sides of the inner tube 22, and the inner tube 22 is disposed on the outer tube 21 Internally, the magnets 23 can emit a magnetic field to allow magnetization to pass through the fluid. However, the plurality of magnets 23 of the conventional fluid magnetization device are interposed on both sides of the inner tube 22 at intervals, so that the magnet 23 is easily detached, and the fluid cannot effectively generate a magnetization reaction.

Further, as shown in Fig. 3, it is a schematic view of still another conventional fluid magnetization apparatus. The conventional fluid magnetization device mainly comprises an outer tube 31, a screw 32, a core 33, a copper coil 34 and two washers 35; the screw 32 is disposed inside the outer tube 31, and the screw 32 has a spiral flow path 321 to provide The fluid core flows; the iron core 33 is disposed inside the screw 32, and the washers 35 are sleeved on opposite ends of the outer tube 31, and the copper coils 34 are wound around the outer wall of the outer tube 31 and located in the two washers 35. The magnetic field A generated by energization of the copper coil 34 can magnetize the fluid in the spiral flow path 321 to generate a magnetized fluid. However, the copper coils 34 of the conventional fluid magnetization device are all wound on the outer tube 31 in the same direction, so that the copper coil 34 can only generate the magnetic field A in a single magnetic direction, and the magnetic direction is in the same direction as the flow direction of the fluid B. As shown in Fig. 4, only the magnetic action zone is generated near the water inlet and the water outlet (the intersection area of A and B in Fig. 4), and the magnetic field strength of the action zone is also relatively weak, so that the magnetization effect is obtained. There are restrictions.

Therefore, how to create a kind of can improve the above-mentioned defects, so that the magnetization effect of the fluid can be further improved, will be the active disclosure of this creative.

In view of the above-mentioned problems of the prior art, the purpose of the present invention is to provide a fluid magnetization device which can enhance the induced magnetic field of the coil to enhance the magnetization effect of the fluid.

According to the purpose of the present invention, a fluid magnetization device is provided, which comprises: an outer tube having a first accommodating space therein; a screw disposed in the first accommodating space, the inner portion of the screw being formed a second accommodating space, and the outer wall of the screw is engraved to form a spiral flow path, and when a fluid flows into the first accommodating space through one end of the outer tube, the flow system follows the spiral flow path toward the outer tube Flowing from the other end; a metal inner core made of a magnetically permeable material is disposed in the second accommodating space, and the lengths of the metal inner core, the outer tube and the screw are corresponding; the plurality of washers are spaced apart from each other The outer wall of the tube, and two of the washers are respectively disposed at opposite ends of the outer tube; and a plurality of copper coils, each of which is wound around the outer wall of the tube between the two spaced spacers, and the phase The adjacent copper coils are respectively disposed on the outer tube in a configuration of forward winding and reverse winding. Wherein, the adjacent copper coils are energized to generate a first magnetic field and a second magnetic field in opposite directions, and the first magnetic field and the second magnetic field are mutually repulsive at the position of the corresponding washer to generate a radial magnetic region. The magnetic field in this zone is reinforced by the inner core of the magnetically permeable material and guided by the flange of the inner core such that the magnetic direction of the radial magnetic zone is perpendicular to the flow direction of the fluid.

According to the purpose of the present invention, a magnetizing fluid generating method is further provided, which comprises the steps of: energizing a plurality of copper coils disposed on an outer wall of one of the fluid magnetizing devices to generate a plurality of magnetic fields, wherein each copper The coils are arranged in sections, and the adjacent copper coils are respectively configured by forward winding and reverse winding, so that adjacent copper coils can generate one of a first magnetic field and a second magnetic field in opposite directions from each other; One end of the tube provides a fluid flow into the interior, allowing the fluid to flow through a spiral flow path of one of the screws provided inside the outer tube, and is subjected to a plurality of radial directions of the first magnetic field and the second magnetic field The magnetic region acts to generate a magnetization reaction, so that a magnetized fluid can be formed when the fluid flows out from the opposite end of the outer tube, wherein the first magnetic field and the second magnetic field have a radial magnetic region due to mutual repulsion. The direction of the magnetic force of the radial magnetic zone is perpendicular to the flow direction of the fluid.

According to the above technical feature, the inner core of the magnetic conductive material comprises a plurality of spaced apart flanges, and the positions of the flanges correspond to the respective washers.

According to the above technical feature, the two ends of the copper coils are respectively connected and fixed to two adjacent spaced spacers.

According to the above technical feature, the periphery of the gasket is provided with a slot to provide copper coil fixing.

According to the above technical feature, the gasket is provided with a perforation to provide copper coil fixing.

According to the above technical feature, the plurality of copper coils are a coil group that is integrally wound.

According to the above technical feature, the outer wall of the outer tube is provided with an external thread on the entire surface to provide a gasket for locking and fixing through the internal thread.

According to the above technical feature, the outer wall of the outer tube is partially provided with an external thread, and the position of the external thread can provide a plurality of washers to be screwed to the outer tube through the internal thread.

According to the above technical feature, the screw system is a Teflon material.

According to the above technical feature, the fluid magnetization device of the present invention further comprises two end caps, each end cap is respectively sleeved on opposite ends of the outer tube, and the outer tube can be connected to a water supply through the two end caps. Device.

In summary, the fluid magnetization device of the present invention mainly generates a plurality of magnetic fields through a plurality of copper coils, and cooperates with a screw and a metal core which can provide a spiral flow of the fluid, so that the fluid can generate a better magnetization reaction. Further, a magnetized fluid is formed. Furthermore, the plurality of copper coils of the present invention are arranged in sections, and the adjacent copper coils are respectively arranged in a forward winding and a reverse winding manner, so that adjacent copper coils can be opposite to each other. a first magnetic field and a second magnetic field, and the first magnetic field and the second magnetic field have a radial magnetic domain due to mutual repulsion, the magnetic field of the magnetic field is reinforced by the inner core of the magnetic material and guided by the flange of the inner core The magnetic direction of the radial magnetic zone is perpendicular to the flow direction of the fluid. In this way, the induced magnetic field of the coil can be effectively enhanced, and the magnetization effect of the fluid can be further improved.

In order to understand the technical characteristics, content and advantages of the creation and the effects that can be achieved by the examiner, the author will use the drawings in detail and explain the following in the form of the examples, and the drawings used therein The subject matter is only for the purpose of illustration and supplementary instructions. It is not necessarily the true proportion and precise configuration after the implementation of the original creation. Therefore, the proportions and configuration relationships of the attached drawings should not be interpreted or limited in the actual implementation scope. First described.

Please refer to FIG. 5, which is a first schematic view of a first embodiment of the fluid magnetization device of the present invention. As shown in the figure, the fluid magnetization device of the present invention comprises an outer tube 41, a screw 42, a metal inner core 43 of a magnetically permeable material, a plurality of washers 44, a plurality of copper coils 45 and two end caps 46, wherein The length of the outer tube 41, the screw 42 and the metal inner core 43 of the magnetically permeable material correspond to each other.

The inside of the outer tube 41 forms a first accommodating space 411, and the opposite ends of the outer tube 41 are provided with a through port, and, in the first embodiment, the outer wall of the outer tube 41 is provided with a whole surface. Thread 412. The inside of the screw 42 forms a second accommodating space 421, and the outer wall of the screw 42 is engraved to form a spiral flow path 421. The magnetic core metal core 43 comprises a plurality of spaced apart flanges 431. In a preferred embodiment, the outer surface of the metal core 43 of the magnetically permeable material may be coated with polytetrafluoroethylene. That is commonly known as Teflon.

Please refer to FIG. 5 and FIG. 14 together. FIG. 14 is a schematic diagram of two embodiments of the gasket of the fluid magnetization device of the present invention. The inner wall of the washer 44 is provided with an internal thread 441 which can be matched with the external thread 412 of the outer tube 41, and as shown in Fig. 14, in one of the aspects, the peripheral edge of the washer 44 is provided. There is a slot 442A, or alternatively, the washer 44 is provided with a through hole 442B, and the slot 442A or the through hole 442B can provide the copper coil 45 to penetrate.

Please refer to FIG. 5, FIG. 6, FIG. 7 and FIG. 8 together. FIG. 6 to FIG. 8 are respectively a second schematic diagram and a third schematic diagram of the first embodiment of the fluid magnetization apparatus of the present invention. And the fourth schematic. As shown in the figure, the screw 42 is disposed in the first accommodating space 411 of the outer tube 41, the metal inner core 43 is disposed in the second accommodating space 421 of the screw 42, and the plurality of washers 44 are spaced apart from each other. The outer wall of the tube 41, and two of the washers 44 are respectively disposed at opposite ends of the outer tube 41, wherein a plurality of washers 44 are threaded through the internal thread 441 and the external thread 412 to be fixed to the outer tube 41, Since the outer wall of the outer tube 41 is provided with external threads 412 on the entire surface, the washers 44 can be adjusted according to requirements. In addition, it should be particularly noted that the positions of the flanges 431 of the metal core 43 of the magnetically permeable material are preferably respectively adapted to the positions of the washers 44.

Following the above, a plurality of copper coils 45 are disposed on the outer wall of the outer tube 41. Further, the copper coils 45 are respectively disposed between the spacers 44 spaced apart from each other, and the adjacent copper coils 45 are respectively The arrangement of the forward winding and the reverse winding is provided on the outer tube 41 as shown in Fig. 8. The two ends of the copper coils 45 are respectively connected and fixed to two adjacently spaced washers 44, and the connection manners can be fixed through the slots 442A or 442B of the washers 44 as shown in FIG. In a preferred embodiment, the plurality of copper coils 45 can be a coil assembly that is integrally wound, but is not limited thereto. The end caps 46 are respectively sleeved on the opposite ends of the outer tube 41, so that the outer tube 41 can be connected to a water supply device through the two end caps 46, and each end cap 46 is respectively provided with a water inlet 461 and A water outlet 462 is provided to provide fluid input and output, wherein the water supply device can be a water purifier or the like.

Please refer to Figure 5 to Figure 11 again. See Figure 9, Figure 10 and Figure 11. Figure 9 is a schematic diagram of the fluid passing through the fluid magnetization device. Figure 10 is the original creation. The fluid magnetization device generates a schematic diagram of a plurality of magnetic fields, and FIG. 11 is a schematic diagram of the magnetic field distribution of the fluid magnetization device of the present invention. The fluid C can be input from the water inlet 461 and enters the first accommodating space 411 from one end of the outer tube 41 and flows to the spiral flow path 422 of the screw 42 so that the fluid C can spirally flow in the first accommodating space 411. Then, the other end of the outer tube 41 is output toward the water outlet 462 as shown in Fig. 9. Since the adjacent copper coils 45 of the present invention are wound in a forward rotation and a reverse rotation manner, the adjacent copper coils 45 can generate one of the first magnetic field D and the second magnetic field E in opposite directions from each other after being energized. A magnetic field D and a second magnetic field E partially overlap at a position corresponding to the washer 44 to generate an overlapping magnetic region F, as shown in FIGS. 10 and 11, and the first magnetic field D and the second magnetic field in opposite directions When E overlaps, a repulsive action is generated to form a radial magnetic direction, which causes the magnetic direction of the radial magnetic domain F to be emitted laterally relative to the outer tube 41 to be perpendicular to the flow direction (longitudinal flow) of the fluid C. As a result, the generation of the overlapping magnetic regions F increases the magnetic field response of the coil, thereby increasing the magnetization effect of the fluid C.

Briefly, the magnetizing fluid generating method of the present invention is as shown in Fig. 15, and the steps are as follows: Step S11: energizing a plurality of copper coils 45 provided on the outer wall of the outer tube 41 of the fluid magnetizing device to generate a plurality of a magnetic field; wherein each copper coil 45 is arranged in sections, and the adjacent copper coils 45 are respectively configured by forward winding and reverse winding, so that the adjacent copper coils 45 can generate the first magnetic field D in opposite directions from each other. With the second magnetic field E. Step S12: using one end of the outer tube 41 to supply the fluid C to the inside, and letting the fluid C flow through the spiral flow path 422 of the screw 42 provided inside the outer tube 41, the first one of the plurality The magnetic field D and the second magnetic field E act to generate a magnetization reaction, so that when the fluid C flows out from the opposite end of the outer tube 41, a magnetized fluid can be formed; wherein the first magnetic field D and the second magnetic field E have mutual exclusion A radial magnetic zone F is generated, the magnetic direction of the radial magnetic zone F being perpendicular to the flow direction of the fluid C.

In the above, it is worth mentioning that since the flange 431 of the metal inner core 43 of the magnetic conductive material is designed to correspond to the position of the washer 44, the design of the flange 431 has been used as a magnetic field guiding function to enhance the diameter. The magnetic force to the magnetic zone F allows the magnetization to be further enhanced.

In addition, please refer to FIG. 12 and FIG. 13 , which are respectively a first schematic diagram and a second schematic diagram of a second embodiment of the fluid magnetization device of the present invention. In the second embodiment, the outer thread 41 is externally disposed, and the outer thread 412 is positioned to provide a plurality of washers 44 that are threaded onto the outer tube 41 by internal threads 441.

Specifically, the fluid magnetization device of the present invention mainly sets the copper coils in sections, and arranges adjacent copper coils in a manner of forward winding and reverse winding, so that adjacent copper coils can be generated. The first magnetic field and the second magnetic field in opposite directions of each other are mutually repelled by the first magnetic field and the second magnetic field to generate a radial magnetic domain whose magnetic direction is perpendicular to the flow direction of the fluid, and the magnetic field of the coil can be effectively enhanced by the radial magnetic field , thereby increasing the magnetization effect of the fluid. In addition, the creation of the metal core of the magnetically permeable material is provided with a plurality of flanges through which the magnetic field direction is guided to strengthen the magnetic force of the radial magnetic domain, so that the fluid can achieve a better magnetization reaction.

Looking at the above, it can be seen that under the previous technology, this creation has indeed achieved the desired effect, and it is not easy for people who are familiar with the art to think about it. Moreover, this creation has not been disclosed before the application, and it has Progressive and practical, it has been in line with the patent application requirements, and the patent application is filed according to law. You are requested to approve the patent application for this piece to encourage creation.

The embodiments described above are only for explaining the technical idea and characteristics of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement them according to the scope of the patent. That is, the equivalent changes or modifications made by the people in accordance with the spirit revealed by this creation should still be covered by the scope of the patent of this creation.

11, 21丶31, 41‧‧‧ outside management
12, 22‧‧‧ internal management
13‧‧‧Water flow tube
131, 211, 461‧‧ ‧ water inlet
132, 212, 462‧‧ ‧ water outlet
14, 34, 45‧‧‧ copper coil
23‧‧‧ Magnet
32, 42‧‧‧ screw
321, 422‧‧‧ spiral flow path
33‧‧‧ iron core
35, 44‧‧‧ washers
411‧‧‧First accommodation space
412‧‧‧ external thread
421‧‧‧Second accommodating space
43‧‧‧Metal core
431‧‧‧Flange
441‧‧‧ internal thread
442A‧‧‧ slotting
442B‧‧‧Perforation
46‧‧‧End cover
A‧‧‧ magnetic field
B, C‧‧‧ fluid
D‧‧‧First magnetic field
E‧‧‧second magnetic field
F‧‧‧Overlapping magnetic zone
S11, S12‧‧‧ steps

Figure 1 is a schematic illustration of a fluid magnetization apparatus of the prior art. Figure 2 is a schematic illustration of another conventional fluid magnetization apparatus. Figure 3 is a schematic view of yet another conventional fluid magnetization apparatus. Fig. 4 is a view showing the direction corresponding to the magnetic field and the fluid of the fluid magnetizing device of the prior art of Fig. 3. Figure 5 is a first schematic view of a first embodiment of the fluid magnetization apparatus of the present invention. Figure 6 is a second schematic view of a first embodiment of the fluid magnetization apparatus of the present invention. Figure 7 is a third schematic view of the first embodiment of the fluid magnetization apparatus of the present invention. Figure 8 is a fourth schematic view of the first embodiment of the fluid magnetization apparatus of the present invention. Figure 9 is a schematic view showing the fluid passage of the fluid magnetization device of the present invention. Figure 10 is a schematic diagram of a plurality of magnetic fields generated by the fluid magnetization device of the present invention. Figure 11 is a schematic diagram of the magnetic field superposition of the fluid magnetization device of the present invention. Figure 12 is a first schematic view of a second embodiment of the fluid magnetization apparatus of the present invention. Figure 13 is a second schematic view of a second embodiment of the fluid magnetization apparatus of the present invention. Fig. 14 is a schematic view showing two embodiments of the gasket of the fluid magnetization device of the present invention. Figure 15 is a flow chart of the method for generating magnetized fluid of the present invention.

41‧‧‧External management

411‧‧‧First accommodation space

412‧‧‧ external thread

42‧‧‧ screw

421‧‧‧Second accommodating space

422‧‧‧Spiral flow channel

43‧‧‧Metal core

431‧‧‧Flange

44‧‧‧Washers

441‧‧‧ internal thread

45‧‧‧ copper coil

46‧‧‧End cover

Claims (10)

A fluid magnetization device comprising: an outer tube (41) having a first accommodating space (411) formed therein; a screw (42) disposed in the first accommodating space (411), The inside of the screw (42) forms a second accommodating space (421), and the outer wall of the screw (42) is engraved to form a spiral flow path (422) through which a fluid (C) passes ( 41) one end flows into the first accommodating space (411), and the fluid (C) flows through the spiral flow path (422) toward the opposite end of the outer tube (41); a metal inner core (43) Is disposed in the second accommodating space (421), and the metal inner core (43), the outer tube (41) and the length of the screw (42) are corresponding; a plurality of washers (44), The spacer is sleeved on the outer wall of the outer tube (41), and two of the washers (44) are respectively disposed at opposite ends of the outer tube (41); a plurality of copper coils (45), each of the copper coils (45) being wound around an outer wall of the outer tube (41) disposed between the two spaced spacers (44), and adjacent to the copper coil (45) And respectively disposed on the outer tube (41) in a configuration of forward winding and reverse winding; wherein the adjacent copper coils (45) are energized to generate one of the first magnetic fields in opposite directions (D) And a second magnetic field (E), and the first magnetic field (D) and the second magnetic field (E) are mutually repelled at a position corresponding to the gasket (44) to generate a radial magnetic domain (F), The direction of the magnetic force of the radial magnetic domain (F) is perpendicular to the flow direction of the fluid (C). The fluid magnetization device of claim 1, wherein the metal core (43) comprises a plurality of flanges (431) spaced apart from each other to provide a magnetic field, and the positions of the flanges (431) are respectively corresponding to the washers (44). The fluid magnetization device of claim 1, wherein the two ends of each of the copper coils (45) are respectively connected and fixed to the two adjacent spacers (44). The fluid magnetization device of claim 3, wherein the periphery of the gasket (44) is provided with a slot (442A) to provide the copper coil (45) for fixing. The fluid magnetization device of claim 3, wherein the gasket (44) is provided with a perforation (442B) to provide the copper coil (45) for attachment. The fluid magnetization device of claim 3, wherein the plurality of copper coils (45) are integrally formed coil sets. The fluid magnetization device of claim 1, wherein the outer wall of the outer tube (41) is provided with an external thread (412) on the entire surface to provide the gasket (44) to be locked and fixed by the internal thread (441). The fluid magnetization device of claim 1, wherein the outer wall of the outer tube (41) is partially provided with an external thread (412), and the external thread (412) is provided at a position to provide the plurality of washers (44) through The thread (441) is screwed onto the outer tube (41). The fluid magnetization device of claim 1, wherein the screw system is a Teflon material. The fluid magnetization device of any one of claims 1 to 9, further comprising two end caps (46), each end cap (46) being respectively sleeved at opposite ends of the outer tube (41) The outer tube (41) can be connected to a water supply device through the two end covers (46).