TWI742734B - Device for generating magnetized water and device for generating magnitized water with bubbles using the same - Google Patents

Abstract

The present provides a device for magnetizing water, comprising a shaft, and a disk structure coupled to the shaft having a plurality of first channels, a first flow inlet coupled to the plurality of first channels, and a plurality of magnetic elements for magnetizing a first flow entering the disk structure. When the shaft is driven to rotate, the disk structure is driven to rotate for generating a negative pressure to suck the first flow from the flow inlet and exhausting the sucked second flow through the plurality of first channels. Alternatively, the present invention further comprises a gas provider for providing a second flow interacting with the first for generating bubbles during the high-speed rotation of the disk structure.

Description

Magnetized liquid generating device and bubble magnetized liquid generating device using the device

The present invention is a technology for generating magnetized liquid and bubbles, in particular, it refers to a kind of liquid generating device that is equipped with magnetic elements on a turntable, and sucks fluid into the turntable by rotation to generate negative pressure to magnetize and generate bubbles, and a device using the device Bubble magnetized liquid generating device.

According to research, after the water is magnetized, the hydrogen bond angle in the water molecule becomes smaller, the water changes from 13-18 large molecular clusters to 5-6 small molecular clusters, and the permeability, pH and solubility of water increase, While the surface tension is reduced, its physical and chemical properties have significant changes. Therefore, the application of magnetized water to agricultural breeding or aquaculture has a significant increase in output. The magical effect of magnetized water can be found in the information that the magnetized water disclosed in the Republic of China Patent Publication No. 201219316 has been proved theoretically.

On the other hand, microbubbles are micro- or nano-sized bubbles formed in the liquid. With the advancement of science and technology, in recent years, people have discovered that such ultra-fine bubbles have many different effects. In different application fields, the gas in the bubble can use different gases, such as oxygen, carbon dioxide or ozone, etc., to be used in various fields of agriculture, food and industry, such as: breeding, environmental protection and clean sewage treatment, Hydroponic crop cultivation, etc. Therefore, if the characteristics of both magnetization and bubbles can be applied to water and liquid treatment, it will increase the use of water or its related liquids in industry, agriculture or people's livelihood.

In conventional technologies, for example, Chinese Patent No. CN 109673337 teaches a device for irrigating rice crops with micro-oxygen bubble magnetized water and a method for irrigating rice crops with micro-oxygen bubble magnetized water, belonging to the technical field of crop irrigation; the micro-oxygen bubble magnetized water irrigation The rice crop device is equipped with a microbubble cavitation tube at the entrance of the waterway, and a microbubble cavitation tank is provided behind the tube, and the microbubble cavitation tube is connected with an aerator. The combination of the three can increase the oxygen content of the irrigation water; The method of irrigating rice crops includes the process of diversion and diffusion and aeration. The ordinary irrigation water is enriched with oxygen by diffusion and oxygen, and the fertilizer dissolution rate in the irrigation water is enhanced by magnetization.

In addition, the Republic of China Patent Publication No. I372077 also teaches a method to provide a bubble generating device that is not restricted by the number of revolutions of the rotary drive source, and can be rotated at a high speed higher than the number of revolutions of the rotary drive source. The part is rotated, and ultra-fine bubbles of nanometer level can be obtained. The feature of the structure is that magnets are respectively arranged between the pump blades and the limiting member and the two ends of the rotating part, and the inner peripheral surface of the outer cylinder facing the outer peripheral surface of the rotating part is arranged along the outer cylinder. A fixed repelling magnet is installed in the axial direction of the rotating part, and a rotating repelling magnet is installed along the axial direction of the rotating part on the outer peripheral surface of the rotating part facing the inner peripheral surface of the outer cylinder, so that the repelling magnet is fixed And the rotational speed increase force caused by the repulsion force generated when the repulsive magnets for revolving repulsion are separated from each other from each other, compared to when the fixed repulsion magnets and the repulsive repulsion magnets are close to each other and face each other The turning resistance caused by the repulsive force is greater.

The invention provides a microfluidic structure and a magnetized liquid generating device. By arranging magnetic elements on the turntable, the high-speed rotation of the turntable accelerates the flow rate of fluid entering the turntable. Due to the increase of the fluid flow rate, the height of the flow path between the first and second disks constituting the turntable can be reduced, and the distance between the magnetic elements arranged on the first and second disks can be reduced, thereby increasing The rate of change of magnetic flux acting on the fluid entering the turntable. In addition, due to the increase in the flow rate of the fluid entering the turntable, it means that the time for the fluid to enter and exit the turntable is shortened. In addition, the smaller the distance between the magnetic elements on the first and second disks increases the rate of change of magnetic flux. According to Ferrari's law, the induced electromotive force acting on the fluid can be increased, thereby increasing the magnetization effect of the fluid.

The invention provides a magnetized liquid generating device and a bubble magnetized liquid generating device using the device. Through the speed difference between the rotation of the rotating shaft and the turntable, a suction force of negative pressure is formed to suck a first fluid into the rotating shaft. The first fluid entering the inside of the shaft passes through the porous structure to form a bubble structure, because the turntable with magnetic elements can magnetize the second fluid, and through the turntable high-speed rotation makes the magnetized fluid cut by the bubbles discharged from the porous structure A plurality of microfluidic structures are formed to form a magnetized liquid with a microfluidic structure.

In one embodiment, the present invention provides a magnetized liquid generating device, which includes a rotating shaft and a turntable. The turntable is connected to the rotating shaft and has a plurality of first flow passages therein, the turntable has a first fluid inlet communicated with the plurality of first flow passages, and the turntable has a plurality of first magnetic elements for magnetization to enter A first fluid in the turntable. Wherein, when the rotating shaft rotates, the turntable is driven to rotate to generate negative pressure, and the first fluid is sucked in from the first fluid inlet, and then magnetized by the plurality of first magnetic elements, and then discharged from the turntable through the plurality of first flow passages. .

In another embodiment, the present invention provides a bubble magnetized liquid generating device, which includes a rotating disk, a rotating shaft, and a gas supply part. The turntable has a plurality of first flow passages therein, the turntable has a first fluid inlet communicating with the plurality of first flow passages, and the turntable has a plurality of magnetic elements for magnetizing a first flow passage into the turntable fluid. The rotating shaft is coupled with the turntable, and the rotating shaft has a hollow flow channel. The gas supply part is arranged on the rotating shaft or the turntable to provide a second fluid. Wherein, when the rotating shaft rotates, the turntable is driven to rotate to generate negative pressure, and the first fluid is sucked in from the first fluid inlet, and then magnetized by the plurality of first magnetic elements, and then discharged from the turntable through the plurality of first flow passages. , Wherein when the negative pressure is generated, the second fluid is discharged through the gas supply part and interacts with the first fluid to generate bubbles.

Hereinafter, referring to the accompanying drawings, various exemplary embodiments may be described more fully, and some exemplary embodiments are shown in the accompanying drawings. However, the inventive concept may be embodied in many different forms, and should not be construed as being limited to the exemplary embodiments set forth herein. To be precise, the provision of these exemplary embodiments makes the present invention detailed and complete, and will fully convey the scope of the concept of the present invention to those skilled in the art. Similar numbers always indicate similar components. Hereinafter, various embodiments and drawings will be used to illustrate the magnetized liquid generating device and the bubble magnetized liquid generating device using the device. However, the following embodiments are not intended to limit the present invention.

Please refer to FIG. 1A, which is a schematic diagram of an embodiment of the magnetized liquid generating device of the present invention. In this embodiment, the magnetized liquid generating device 2 includes a rotating shaft 20 and a rotating disk 21. The rotating shaft 20 is coupled to the motor body 22 through a bearing 220. It should be noted that the motor body 22 includes the main winding rotor and stator structures of the motor, which are well known to those with ordinary knowledge in the art, and will not be repeated here. The two ends 24 and 25 of the rotating shaft 20 are respectively coupled to the rotating disk 21 and a rotating shaft seat 26. Driven by the motor body 22, the rotating shaft 20 can be rotated, and the turntable 21 can be driven to rotate.

The turntable 21 is connected to the rotating shaft 20. The turntable 21 has a plurality of first flow passages 210 therein, the turntable 21 has a first fluid inlet 211 communicating with the plurality of first flow passages 210, and the turntable 21 has a plurality of first flow passages. A magnetic element 23 is used to magnetize a first fluid F1 entering the turntable 21. In this embodiment, the turntable 21 is an impeller. In this implementation, the first fluid F1 is a liquid, such as water, but it is not limited thereto. In this embodiment, the turntable 21 further has a first plate body 212 and a second plate body 213 corresponding to the first plate body 212, between the first plate body 212 and the second plate body 213 There is a space 214 in which a plurality of cycloid ribs 215 are formed, and the first flow channel 210 is formed between two adjacent cycloid ribs 215. In this embodiment, the first fluid inlet 211 is provided on the first plate body 212. It should be noted that the first disc body 212 and the second disc body 213 may be separate components combined with each other to form a turntable, or the first disc body 212 and the second disc body 213 may be an integral structure. The turntable 21 can be made of metal material or polymer plastic.

Please refer to FIGS. 1A and 2A and 2B at the same time. FIG. 2A is a schematic cross-sectional view of an embodiment of the turntable of the present invention; FIG. 2B is a schematic top view of an embodiment of the turntable of the present invention. In this embodiment, the turntable 21 has a first fluid inlet 211 formed on the side of the first disc body 212, and a second fluid inlet 218 is formed on the side of the second disc body 213. Wherein, the first fluid F1 is sucked by the negative pressure generated when the turntable 21 rotates, and enters the turntable 21 from the first fluid inlet 211, and then enters the first flow channel 210. The end 24 of the rotating shaft 20 is airtightly coupled with the second fluid inlet 218, so that when the rotating shaft 20 rotates, the turntable 21 can be driven to rotate. A plurality of disc plates 216 between adjacent cycloidal convexes 215 on the first disc body 212 and a plurality of disc plates 217 between adjacent cycloidal convexes 215 on the second disc body 213 are arranged. First magnetic element 23. In this embodiment, the first disc body 212 and the second disc body 213 respectively have corresponding first magnetic elements 23, which include a first magnetic element 23a embedded on the first disc body 212 and embedded Each of the first magnetic elements 23b on the second disk body 213 has a corresponding first magnetic element 23b. In an embodiment, the first disk body 212 and the second disk body 213 may be provided with accommodating holes 219, and then the magnetic elements 23a and 23b may be embedded in the accommodating holes 219, respectively. The polarities of the corresponding surfaces of the first magnetic element 23a and the first magnetic element 23b are opposite to each other. For example, in FIG. 2A, the S pole of the first magnetic element 23a on the first disc body 212 corresponds to the N pole of the first magnetic element on the second disc body 213. In another embodiment, the N pole of the first magnetic element 23a on the first disk body 212 may correspond to the S pole of the second disk body 213.

Please refer to FIG. 1B and FIG. 2C, which are schematic diagrams of another embodiment of the magnetized liquid generating device of the present invention; FIG. 2C is a schematic top view of the turntable of FIG. 1B. In this embodiment, it is basically similar to FIG. 1A. The difference is that the position of the first magnetic element 23 on the turntable 21a in this embodiment is different from that in FIG. 1A. In this embodiment, at least one cycloid protrusion 215 has a plurality of containing holes 219 for placing the plurality of first magnetic elements 23. In another embodiment, the accommodating hole 219 penetrating the first disc body 212, the cycloidal cam 215, and the second disc body 213 may be formed at a position corresponding to the cycloidal cam, and then the magnetic element 23 can be embedded in the accommodating hole 219.孔219.

Please refer to FIG. 3A and FIG. 3B, which are schematic diagrams of different embodiments of the magnetized liquid generating device of the present invention. In the embodiment of FIG. 3A, the first fluid inlet 211 on the first disk body 212 side of the turntable 21b is connected to one end of the rotating shaft 20, and the rotating shaft 20 has a hollow flow channel 200 inside to provide the first fluid of the external environment to enter The hollow runner. The other end 25 of the rotating shaft 20 is coupled with the rotating shaft seat 26 so that the end 25 can rotate in the rotating shaft seat 26. In this embodiment, the shaft seat 26 has an inlet 260, and the shaft end 25 has a first inlet 251 that communicates with the inlet 260 and the hollow flow passage 200 in the shaft 20, so that the first fluid F1 can be borrowed. The negative pressure generated when the turntable 21b is rotated by the rotating shaft 20 sucks the first fluid F1 from the inlet 260, enters the hollow flow passage 200 through the first inlet 251, and then enters the first flow passage 210 through the turntable 21b, Then it is thrown out of the turntable 21b at a high speed. In this embodiment, the turntable 21b has magnetic elements 23a and 23b, and the arrangement is as shown in FIG. 1A, and will not be repeated here. When the first fluid F1 passes through each first flow channel 210, it can be magnetized by the magnetic elements 23a and 23b. As shown in FIG. 3B, in this embodiment, it is basically similar to FIG. 3A, except that the arrangement of the magnetic element 23 on the turntable 21c is different from that of FIG. 3A. The arrangement of the magnetic element 23 in this embodiment is the same as that shown in FIG. 1B, and is arranged in the cycloid convex 215, which will not be repeated here.

變化率。此外，由於進入轉盤21內的第一流體F1流速增加，代表第一流體F1進入到轉盤21內以及流出轉盤21的時間 d t 縮短，因此，根據法拉利定律，如下式(1)所示，可以增加作用於流體的感應電動勢ε，進而增加對第一流體F1的磁化效果。

…………..(1) Next, the principle of the aforementioned magnetization will be explained. Taking FIG. 1A as an example, by arranging magnetic elements 23a and 23b on the turntable 21, the turntable 21 is rotated at a high speed to accelerate the flow rate of the first fluid F1 entering the turntable 21. Due to the increase in the flow rate of the first fluid F1, the height H of the flow path between the first disc body 212 and the second disc body 213 constituting the turntable 21 can be reduced, and the arrangement on the first disc body 212 and the second disc body 213 can be reduced. The distance d between the magnetic elements 23a and 23b increases the magnetic flux acting on the first fluid F1 in the turntable 21

Rate of change. In addition, since the flow rate of the first fluid F1 entering the turntable 21 increases, it means that the time dt for the first fluid F1 to enter the turntable 21 and flow out of the turntable 21 is shortened. Therefore, according to Ferrari's law, as shown in the following equation (1), it can be increased The induced electromotive force ε acting on the fluid further increases the magnetization effect on the first fluid F1.

…………..(1)

Please refer to FIG. 4A, which is a schematic diagram of an embodiment of the bubble magnetized liquid generating device of the present invention. In this embodiment, the bubble magnetized liquid generating device 3 is a pumping device, which includes a housing 30, a rotating shaft 20, a rotating disk 21 and a gas supply part 27. The housing 30 has a motor body 22 and a bearing 220 that drives the rotation shaft 20 to rotate, and a rotation shaft seat 26 is provided on one side of the housing 30 to couple with the end 25 of the rotation shaft 20. The other end of the housing has a first fluid inlet 211 for providing the first fluid F1 to enter, and the other end has a fluid outlet 31 for discharging fluid. It should be noted that the structure of the pump is well known to those skilled in the art, so it will not be repeated here. The shaft 20 has a hollow flow channel 200 for guiding the second fluid F2. In this embodiment, the second fluid is a gas, such as air, oxygen, carbon dioxide, or ozone, but it is not limited thereto. The turntable 21 is coupled to the rotating shaft 20. The turntable 21 has a plurality of first flow passages 210 therein. The turntable 21 has a first fluid inlet 211 and a second fluid inlet 218, respectively communicating with the plurality of first flow passages 210 . The turntable 21 has a plurality of magnetic elements 23, including a magnetic element 23b disposed on the first disc body 212 and a magnetic element 23a on the second disc body 213, which are used to magnetize a first part in the turntable 21. Fluid F1. In this embodiment, the first fluid F1 is a liquid, such as water. In this embodiment, one end of the rotating shaft 20 is coupled to the second fluid inlet 218 on the turntable 21 so that the hollow flow channel 200 can communicate with the plurality of first flow channels 210. The structure of the turntable 21 is the same as the structure shown in FIGS. 2A and 2B, and the configuration of the magnetic element 23 is also shown in FIGS. 2A and 2B, which will not be repeated here.

The gas supply part 27 can be optionally arranged on the rotating shaft 20 or the rotating disk 21 to provide a second fluid F2. In this embodiment, the second fluid F2 is a gas, such as air, oxygen, carbon dioxide, or ozone. In this embodiment, the gas supply part 27 is disposed on the rotating shaft 20 and includes a fixed shaft 270 and a porous disk body 273. The fixed shaft 270 has a guiding flow channel 271 connected to the hollow flow channel 200 to guide the second fluid F2 into the plurality of first flow channels 210 in the turntable 21. In this embodiment, the guiding flow channel 271 is coaxial with the hollow flow channel 200. The fixed shaft 270 of the present force is connected to one end of the rotating shaft 20 through the peripheral screw structure.

The porous disk body 273 is fixed on the fixed shaft 270. In this embodiment, one surface of the porous disk 273 is blocked by the end of the fixed shaft 270 for positioning, and the other surface abuts against the shaft 20. The upper stopper 274 is used to fix the porous disk body 273 on the rotating shaft 20. The porous disk body 273 is connected with the guiding channel 271 to receive the second fluid F2. In this embodiment, the fixed shaft 270 communicates with the porous disk body 273 through a lateral flow channel 272. It should be noted that the manner in which the fixed shaft 270 communicates with the porous disk body 273 is not limited to the illustrated embodiment. Those skilled in the art can choose an appropriate connection method according to actual needs. In this embodiment, the porous disk body 273 is disposed in the first fluid inlet 211. When the fixed shaft 270 is fixed on the end of the rotating shaft 20, the porous disk body 273 and the first fluid inlet The wall 2110 of the turntable 21 of 211 has a gap G for providing the first fluid F1 to enter the turntable 21, wherein the second fluid F2 enters the flow passage 272 through the guide flow passage 271, and then enters the plurality of fluids F1. The porous disk body 273 is then discharged from the periphery of the porous disk body 273.

Next, the mechanism of generating bubbles in the embodiment of FIG. 4A will be described. When the rotating shaft 20 is driven by the motor body 22 to rotate, the rotating shaft 20 drives the rotating disc 21 to rotate to generate negative pressure to transfer the first fluid F1 from the first fluid inlet. 211 inhalation. At the same time, the second fluid F2 will also be sucked into the hollow flow channel 200 in the rotating shaft 20 due to negative pressure, and enter the porous disk body 273, because the porous disk body 273 is fixed on the rotating shaft 20, so when the rotating shaft 20 rotates , The porous disk body 273 also rotates to generate centrifugal force. The centrifugal force increases as it is farther away from the rotation axis, so the second fluid F2 can be separated from the surface of the porous disk body 273 in the thickness direction. The second fluid F2 separated from the porous disk body 273 interacts with the first fluid F1 entering through the gap G, so that the first fluid F1 cuts the second fluid F2 into tiny bubbles. The tiny bubbles flow into the turntable 21 along with the first fluid F1, and are discharged out of the turntable 21 through the plurality of first flow channels 210 through the centrifugal force generated by the rotation of the turntable 21. Since the turntable 21 has a plurality of magnetic elements 23a and 23b, the bubble fluid entering the turntable 21 is magnetized by the magnetic elements 23a and 23b on the turntable 21 to form a mixed fluid F3 with magnetized bubbles and then discharged from the fluid outlet 31. The principle of magnetization is as mentioned above, so I won’t repeat it here.

Please refer to FIG. 4B, which is a schematic diagram of another embodiment of the bubble magnetized liquid generating device of the present invention. In this embodiment, the bubble magnetized liquid generating device 3a is basically similar to FIG. 4A. The difference is that the magnetic element 23 of the bubble magnetized liquid generating device 3a in this embodiment is set in the cycloid convex 215. The manner is the same as that shown in FIG. 1B or FIG. 3B, which will not be repeated here.

Please refer to FIGS. 4C and 4D, where FIG. 4C is a schematic diagram of another embodiment of the bubble magnetized liquid generating device of the present invention; and FIG. 4D is a three-dimensional schematic diagram of the turntable in FIG. 4C. In this embodiment, the turntable 21d of the bubble magnetized liquid generating device 3b has a plurality of first flow channels 210 and a plurality of second flow channels 2120 and 2130. The end of the rotating shaft 20 is coupled to the second fluid inlet 218 of the rotating disk 21d. In this embodiment, the end of the rotating shaft 20 has a fluid channel 201 communicating with the hollow flow passage 200 to guide the second fluid F2 entering the hollow flow passage 200 in the rotating shaft 20. On the wall surface of the second fluid inlet 218 is provided a relay flow channel 2180 communicating with the second flow channels 2120 and 2130 and the fluid channel 201.

In this embodiment, the plurality of second flow passages 2120 and 2130 are respectively opened inside the first disc body 212 and the second disc body 213 for guiding the second air flow F2. In the thickness direction of the first disc body 212 and the second disc body 213 on both sides of the outlet of the first flow channel 210, a porous structure 274 is provided. In this embodiment, the porous structure 274, the fluid channel 201, and the second flow channels 2120 and 2130 constitute the gas supply portion 27a. The porous structure 274 in this embodiment is a ring-shaped porous structure, and a 360-degree ring is provided on the impeller bodies of the first disk body 212 and the second disk body 213. It should be noted that the porous structure 274 of the gas supply part 27a is not limited to a 360-degree ring structure. In another embodiment, the porous structure 274 may be a plurality of sub-porous structures distributed on the turntable 21d. The upper and lower layers of the first and second disk bodies 212 and 213 are on the circumferential area in the thickness direction.

In addition, the end of the rotating shaft 20 close to the outside of the inlet end 202 has a flow and flow rate adjusting valve 28 coupled to the inlet end 202. In this embodiment, the flow rate and flow rate adjustment valve 28 has a knob 281 through which the opening size of the valve body 280 can be adjusted by the flow rate and flow rate adjustment valve 28 to control the flow rate and flow rate of the air flow entering the hollow flow channel 200. It should be noted that the flow and flow rate adjusting valve 28 is a component set according to requirements, and is not an essential component necessary to realize the present invention.

When the rotating shaft 20 rotates at a high speed to drive the turntable 21d to rotate, a negative pressure will be generated on the first fluid inlet 211 side of the turntable, and the first fluid F1 will enter the first flow channel 210 inside the turntable 21d from the first fluid inlet 211 through the high-speed The centrifugal force generated by the rotating turntable 21d is thrown out of the turntable 21d from the outlet of the first flow channel 210. At the same time, due to the high-speed rotation of the turntable 21d, the negative pressure inside the rotating shaft 20 will draw the second fluid F2 outside the rotating shaft 20, such as air, into the hollow flow channel 200 through the flow and velocity adjustment valve 28 according to the Bailiye law. . The second fluid F2 flowing into the hollow flow channel 200 enters the second flow channels 2120 and 2130 through the fluid channel 201 and the relay flow channel 2180, and then is discharged through the porous structure 274 of the gas supply part 27a. Since the turntable 21d rotates at a high speed, the first fluid F1 thrown out of the turntable 21d cuts the second fluid F2 discharged from the porous structure 274 of the gas supply part 27a into microbubbles and the first fluid F1 to form a mixed fluid F3 to be discharged.

Please refer to FIG. 5A and FIG. 5B, which are schematic diagrams of two other embodiments of the bubble magnetized liquid generating device of the present invention. In the embodiment of FIG. 5A, the gas supply part 27b of the bubble magnetized liquid generating device 3c is provided on the rotating shaft 20. In one embodiment, the gas supply portion 27b is a ring-shaped porous structure, which is ring-shaped on the wall surface of the rotating shaft 20. The outer surface of the gas supply part 27b is in contact with the external environment, and the inner surface is connected with the hollow flow channel 200. In another embodiment, the gas supply part 27b can also be arranged around the rotating shaft 20 by a plurality of porous structures at equal intervals, for example, a plurality of porous structures are embedded in the rotating shaft 20. In addition, at least one magnetic element 23c is further provided on the rotating shaft 20. In this embodiment, the magnetic element 23c is arranged on the rotating shaft 20 in a ring-shaped structure. In another embodiment, a plurality of magnetic elements 23c may be arranged around the rotating shaft 20 at equal intervals. For example, a plurality of magnetic elements 23c may be embedded in a plurality of openings on the rotating shaft 20.

In this embodiment, one end of the rotating shaft 20 is coupled to the turntable 21 c, and the other end 25 is coupled to the rotating shaft seat 26. The end 25 of the rotating shaft can be rotated in the rotating shaft seat 26. The end portion 25 of the rotating shaft is provided with a fluid channel 250, and the rotating shaft seat 26 is also provided with a fluid channel 260, and the two are communicated with each other. In this embodiment, the fluid channel 250 has a first inlet 251 communicated with the fluid channels 250 and 260 to provide a first fluid F1. In this embodiment, liquid, such as water, passes through and then enters the hollow flow channel. 200. When the rotating shaft 20 rotates at a high speed, the turntable 21c is driven to rotate at a high speed to generate negative pressure. The suction force of the negative pressure sucks the first fluid F1 into the hollow flow channel 200, and then enters the turntable 21c. At the same time, the porous structure of the gas supply part 27b sucks the second fluid F2 from the external environment, which is air in this embodiment, into the hollow flow channel 200 due to the negative pressure. Therefore, when the first fluid F1 passes through the position corresponding to the gas supply part 27b, the high-speed first fluid F1 will cut the second fluid F2 entering the hollow flow channel 200 from the porous structure of the gas supply part 27b into the tiny bubble structure. Then, during the flow of the first fluid F1 containing bubbles, it is magnetized by the magnetic element 23c and the magnetic element 23 on the turntable 21c to form a magnetized bubble fluid. It should be noted that although the magnetic element of the turntable 21c shown in FIG. 5A is arranged on the cycloid convex 215 of the turntable 21c, in another embodiment, the turntable may also be the turntable 21b as shown in FIG. 3A.

Please refer to FIG. 5B. In this embodiment, the bubble magnetized liquid generating device 3d is basically similar to FIG. 5A. The difference is that the second fluid F2 in this embodiment enters in a way different from that in FIG. 5A. In FIG. 5B, the shaft end 25 coupled with the shaft seat 26 is provided with a fluid channel 250, and the shaft seat 26 is also provided with a fluid channel 260 communicating with the fluid channel 250, wherein the fluid channel 250 is coaxial with the hollow flow channel of the shaft 20 Towards. In this embodiment, the fluid channel 250 has a first inlet 251 and a second inlet 252, wherein the first inlet 251 is used to provide the first fluid F1 to enter the fluid channel 250, and the second inlet 252 and the fluid The passage 260 and 250 are connected to guide the second fluid F2 entered by the fluid passage 260 to enter the fluid passage 250. In this embodiment, the fluid channel 260 serves as a gas supply part for providing the second fluid F2 for generating bubbles to enter the fluid channel 250 in the end 25 of the rotating shaft. When the rotating shaft 20 rotates at a high speed, the turntable 21c is driven to rotate at a high speed to generate negative pressure. The suction of negative pressure sucks the first fluid F1 from the first inlet 251 into the fluid channel 250; the suction of negative pressure also sucks the second fluid F2 from the fluid channel 260 into the fluid channel 250. Therefore, when the first fluid F1 passes through the position of the fluid channel 260 as a gas supply part, the high-speed first fluid F1 will cut the second fluid F2 entering the fluid channel 250 from the fluid channel 260 into tiny bubble structures. Then, during the flow of the first fluid F1 containing bubbles, it is magnetized by the magnetic element 23c and the magnetic element 23 on the turntable 21c to form a magnetized bubble fluid. It should be noted that although the magnetic element of the turntable 21c shown in FIG. 5B is arranged on the cycloid convex 215 of the turntable 21c, in another embodiment, the turntable may also be the turntable 21b as shown in FIG. 3A.

Please refer to FIG. 6, which is a schematic diagram of another embodiment of the bubble magnetized liquid generating device of the present invention. In this embodiment, the bubble magnetized liquid generating device 3e adopts the structure of FIG. 5B, and the turntable adopts the turntable 21b as shown in FIG. 3B. The bubble magnetized liquid generating device 3e further has a container 4 with a liquid 40 inside, which is water in this embodiment. One end of the liquid pipe 41 is arranged in the container 4, and the other end is coupled to the first inlet 251 of the bubble magnetized liquid generating device 3e. When the rotating shaft 20 rotates at a high speed, the turntable 21b is driven to rotate at a high speed to generate negative pressure. The suction force of the negative pressure sucks the first fluid F1 from the container 4 into the first inlet 251 via the pipeline 41, enters the hollow flow channel 200 via the fluid channel 250 in the shaft end 25, and then enters the turntable 21b. At the same time, because of the negative pressure, the second fluid F2 of the external environment, which is air in this embodiment, is sucked into the fluid channel 250 in the end 25 of the rotating shaft through the gas supply part, which is the fluid channel 260 in this embodiment. Therefore, when the first fluid F1 passes through the position of the fluid channel 250, the high-speed first fluid F1 will cut the second fluid F2 entering the fluid channel 250 from the fluid channel 260 into tiny bubble structures. Then, the first fluid F1 containing bubbles is magnetized by the magnetic element 23c and the magnetic elements 23a and 23b on the turntable 21b during the flow process to form a mixed fluid F3 of magnetized bubbles, which is discharged from the first flow channel 210 of the turntable 21b. Through a plurality of cycles, a mixed fluid F3 with a plurality of microbubbles can be formed in the container 4.

The above description only describes the preferred implementations or examples of the technical means adopted by the present invention to solve the problems, and is not used to limit the scope of implementation of the patent of the present invention. That is to say, all changes and modifications that are consistent with the scope of the patent application of the present invention or made in accordance with the scope of the patent of the present invention are all covered by the scope of the patent of the present invention.

2: Magnetized liquid generating device

20: shaft

200: Hollow runner

201: fluid channel

202: Import side

21, 21a~21c: turntable

210: first runner

211: First fluid inlet

212: first disc body

2120: second runner

213: The second disc body

2130: second runner

214: Space

215: Cycloid convex

218: Second fluid inlet

219: accommodating hole

22: Motor body

220: bearing

23, 23a, 23b, 23c: magnetic components

24: end

25: End of shaft

250, 251: fluid channel

251: First Entry

252: Second Entry

26: Rotating shaft seat

260: fluid channel

27, 27a~27b: Gas supply department

270: fixed shaft

271: Guiding Runner

272: Runner

273: Porous Disk

274: Porous structure

28: Flow and velocity adjustment valve

280: Valve body

281: Explosion

3. 3a~3e: bubble magnetized liquid generating device

30: shell

31: fluid outlet

4: container

40: liquid

41: Pipeline

F1: First fluid

F2: second fluid

F3: Mixed fluid

FIG. 1A is a schematic diagram of an embodiment of the magnetized liquid generating device of the present invention. FIG. 1B is a schematic diagram of another embodiment of the magnetized liquid generating device of the present invention. 2A is a schematic cross-sectional view of an embodiment of the turntable of the present invention. FIG. 2B is a schematic top view of the embodiment of the turntable in FIG. 2A of the present invention. 2C is a schematic top view of the embodiment of the turntable shown in FIG. 1B of the present invention. 3A and 3B are schematic diagrams of different embodiments of the magnetized liquid generating device of the present invention. 4A is a schematic diagram of an embodiment of the bubble magnetized liquid generating device of the present invention. 4B is a schematic diagram of another embodiment of the bubble magnetized liquid generating device of the present invention. 4C is a schematic diagram of another embodiment of the bubble magnetized liquid generating device of the present invention. Fig. 4D is a three-dimensional schematic diagram of the impeller in Fig. 4C. 5A and 5B are respectively schematic diagrams of two other embodiments of the bubble magnetized liquid generating device of the present invention. Fig. 6 is a schematic diagram of another embodiment of the bubble magnetized liquid generating device of the present invention.

2: Magnetized liquid generating device

20: shaft

200: Hollow runner

21: turntable

210: first runner

211: First fluid inlet

212: first disc body

213: The second disc body

214: Space

215: Cycloid convex

218: Second fluid inlet

22: Motor body

23, 23a, 23b: magnetic components

24: end

25: end

F1: First fluid

Claims (21)

A magnetized liquid generating device includes: a rotating shaft; and a rotating disk connected to the rotating shaft, and having a plurality of first flow passages therein, the rotating disk having a first fluid inlet communicated with the plurality of first flow passages, and the rotating disk There are a plurality of first magnetic elements for magnetizing a first fluid entering the turntable, wherein the turntable further has a first disk body and a second disk body corresponding to the first disk body. There is a space between a disc body and the second disc body, a plurality of cycloid ribs are formed in it, the first flow channel is formed between two adjacent cycloid ribs, and the first fluid inlet is arranged in the first On a disk body; wherein, when the rotating shaft rotates, the rotating disk is driven to rotate to generate negative pressure. The first fluid is sucked from the first fluid inlet and magnetized by the plurality of first magnetic elements, and then the plurality of first magnetic elements The flow path discharges the turntable. The magnetized liquid generating device according to claim 1, wherein the first disc body and the second disc body are integrally formed. The magnetized liquid generating device according to claim 1, wherein at least one cycloid projection has the plurality of first magnetic elements. The magnetized liquid generating device according to claim 1, wherein the disk plate between adjacent cycloid convexes of the first plate body and between the adjacent cycloid convexes of the second plate body The plurality of first magnetic elements are arranged on the disk board. A magnetized liquid generating device includes: a rotating shaft; and A turntable is connected to the rotating shaft and has a plurality of first flow passages therein, the turntable has a first fluid inlet communicating with the plurality of first flow passages, and the turntable has a plurality of first magnetic elements for magnetization A first fluid entering the turntable; wherein the rotating shaft further has a hollow flow passage, one end of which has a first inlet for providing the first fluid to enter the hollow flow passage, and is coupled to the first fluid inlet The other end has a flow outlet connected to the first fluid inlet, so that the first fluid enters the turntable through the outflow outlet. When the rotating shaft rotates, the turntable is driven to rotate to generate negative pressure. The first fluid is transferred from the first fluid inlet to the first fluid. After being sucked in and magnetized by the plurality of first magnetic elements, the turntable is discharged from the plurality of first flow channels. The magnetized liquid generating device according to claim 5, which further has a container containing the first fluid, and a pipeline, wherein one end of the pipeline is connected to the first inlet, and the other end of the pipeline It is connected with the container to provide the first fluid in the container to enter the pipeline, and the first inlet is guided through the pipeline. The magnetized liquid generating device according to claim 5, wherein the rotating shaft is further provided with a second magnetic element for magnetizing the first fluid entering the hollow flow channel. A bubble magnetized liquid generating device includes: a turntable with a plurality of first flow passages therein, the turntable has a first fluid inlet communicating with the plurality of first flow passages, and the turntable is provided with a plurality of magnetic elements for A first fluid magnetized into the turntable; a rotating shaft coupled to the turntable, the rotating shaft having a hollow flow channel; and a gas supply part, provided on the rotating shaft or the rotating disk, for providing a second fluid ; Wherein, when the rotating shaft rotates, the turntable is driven to rotate to generate negative pressure. The first fluid is sucked from the first fluid inlet and magnetized by the plurality of first magnetic elements, and then the plurality of first flow channels The turntable is discharged, wherein when the negative pressure is generated, the second fluid is discharged through the gas supply part and interacts with the first fluid to generate bubbles. The bubble magnetized liquid generating device according to claim 8, wherein the turntable further has a first disc body and a second disc body corresponding to the first disc body, the first disc body and the second disc body There is a space in between, a plurality of cycloid ribs are formed in the space, and the first flow channel is formed between two adjacent cycloid ribs. The bubble magnetized liquid generating device according to claim 9, wherein the first disc body and the second disc body are integrally formed. The bubble magnetized liquid generating device according to claim 9, wherein at least one cycloid projection has the plurality of first magnetic elements. The bubble magnetized liquid generating device according to claim 9, wherein the disk plate between adjacent cycloid convexes of the first plate body and between the adjacent cycloid convexes of the second plate body The plurality of first magnetic elements are provided on the disk board of. The bubble magnetized liquid generating device according to claim 9, wherein the first fluid inlet is provided on the first plate, and the first fluid inlet is coupled with the rotating shaft, so that the first fluid inlet is connected to the hollow flow The roads are connected. The bubble magnetized liquid generating device according to claim 13, wherein one end of the hollow flow channel has a first inlet for providing the first fluid to enter the hollow flow channel, and the other end has a first flow outlet and the first fluid The inlet is connected so that the first fluid enters the turntable through the outlet. The bubble magnetized liquid generating device according to claim 13, which further has a container containing the first fluid, and a pipeline, wherein one end of the pipeline is connected to the first inlet, and the other of the pipeline One end is connected with the container to provide the first fluid in the container to enter the pipeline. The bubble magnetized liquid generating device according to claim 15, wherein the gas supply part is provided with a second inlet on the rotating shaft for generating bubbles by providing a second fluid with the first fluid by the negative pressure. The bubble magnetized liquid generating device according to claim 8, wherein the rotating shaft further has a second magnetic element for magnetizing the first fluid entering the hollow flow channel. The bubble magnetized liquid generating device according to claim 8, wherein the gas supply portion has a porous structure arranged along the shaft wall of the rotating shaft to communicate with the hollow flow passage, and the negative pressure generated when the rotating shaft rotates The external second fluid is sucked into the porous structure and discharged to the hollow flow channel, and then cut by the first fluid passing through the hollow flow channel to generate bubbles. The bubble magnetized liquid generating device according to claim 9, wherein the first fluid inlet is provided on the first disc body, the second disc body has a second fluid inlet communicating with the hollow flow passage of the rotating shaft, the The hollow flow channel sucks in the second fluid from the outside by the negative pressure. The bubble magnetized liquid generating device according to claim 19, wherein the gas supply portion has a porous structure arranged along a circumferential area in the thickness direction of the outer edge of the turntable, and at least one second flow channel arranged in the turntable , The second flow channel has a guide inlet connected to the hollow flow channel, a guide outlet of the second flow channel is connected to the porous structure, and the second flow channel is used to guide the hollow flow channel The second fluid enters the porous structure and is discharged from the porous structure. The bubble magnetized liquid generating device according to claim 19, wherein the gas supply part is arranged at the first fluid inlet and is connected to the rotating shaft, and the gas supply part further includes: a fixed shaft with a guide inside A flow channel communicated with the hollow flow channel to guide the second fluid in the hollow flow channel; and A porous disc body, fixed on the fixed shaft, connected with the guide channel for receiving the second fluid, and a gap between the porous disc body and the wall of the turntable constituting the first fluid inlet , Used to provide the first fluid to enter the turntable, wherein the second fluid enters the porous disk body through the guide channel, and then is discharged from the periphery of the porous disk body, and the discharged second fluid passes through the The first fluid cuts into the gap to form bubbles.

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