KR20090011515U - - microbubble gasliquid mixing device - Google Patents

Abstract

A microbubble gas-liquid mixing device is mounted and disposed in the sanitary installation, the sanitary installation having one or more faucets, and the water source treated by the microbubble gas-liquid mixing device is introduced into the faucet. The microbubble gas-liquid mixing device includes a pump and a helical tube, and air is introduced into the pump and the helical tube through a first gas inlet valve disposed at the front end of the pump, and the water source and the gas-liquid phase It is mixed with to form a large amount of fine bubbles, thereby achieving the effect of increasing the oxygen content of water.

Water, Air, Mixed, Bubble, Clean Water

Description

Microbubble gas-liquid mixing unit {MICROBUBBLE GAS­LIQUID MIXING DEVICE}

The present invention relates to a water-treatment device, in particular a microbubble gas-liquid mixing device, wherein the mixing device can increase the oxygen content of the water, and the mixing device is characterized by the fact that the air inside the water together with the water source It is possible to form the microbubble discharged.

There is a microbubble water treatment apparatus 9 of the prior art as shown in FIG. 7, which includes a motor 91, a pressure tank 92 and a high oxygen dissolving mechnism 93. It is mainly composed of). Motor 91 pressurizes water to flow through first flow channel 94 and reach pressure tank 92. The first flow channel 94 has an air valve 95 for supplying air to the first flow channel 94, which air will flow into the pressure tank 92 along with the water stream. At this time, high pressure will be applied to the water and air stored in the pressure tank 92, so that the air is dissolved in water to form bubbles.

 The high oxygen dissolution mechanism 93 described above is in communication with the pressure tank 92 through the second flow channel 94. The inner flow channel of the high oxygen dissolution mechanism 93 is designed to change the water flow rate and to reduce the size of the bubbles dissolved in the water.

However, although the aforementioned microbubble water-treatment device 9 can increase the dissolved oxygen content of water, the members of the microbubble water-treatment device 9 are complicated, and in achieving the effect of a large amount of dissolved oxygen content, A pressure tank 92 that cooperates with the high oxygen dissolution mechanism 93 is essential. In addition, the primary inlet air and high pressure oxygen dissolution make this effect very limited. As a result, there is a need for an improved apparatus.

The primary object of the present invention for solving the above problems is to provide a microbubble gas-liquid mixing device, in which the microbubble gas-liquid mixing device is arranged in a spiral tube, inlet air of the gas inlet valve, and pump By pressurization, air dissolves into the water and forms a large amount of fine bubbles.

To achieve the above object, the present invention provides a microbubble gas-liquid mixing device which is mounted and disposed in a sanitary fixture, wherein the sanitary fixture comprises one or more faucets and the microbubble gas- A water source treated by a liquid mixing device is introduced into the faucet, characterized by the following:

The microbubble gas-liquid mixing device comprises one or more pumps, and a helical tube; The pump has a water inlet end and a water outlet end, the water inlet end communicates with the water outlet end, at least a first gas inlet valve is disposed at the water inlet end, and the water outlet end is a water supply channel. In which air is introduced by the first gas inlet valve and into the pump such that the pump pressurizes the air and water source for gas-liquid mixing and then transfers the mixture from the water outlet end to the water supply channel, The air and water sources are swirled in the spiral tube by the spiral tube communicating with the water supply channel such that the gas-liquid mixed water source contained in the water supply channel flows into the spiral tube and once again gas-liquid mixed. Allow oxygen-rich water source from the helical tube To be discharged.

In addition, according to the present invention, an adjustment valve is additionally arranged in the water supply channel to adjust the water flow capacity from the water supply channel to the spiral tube while simultaneously adjusting the outlet water pressure from the water supply channel to the spiral tube. .

In addition, according to the present invention, the gas-liquid mixing device further includes a gas-liquid mixing tank, and the gas-liquid mixing tank is provided with a gate valve seat to close in the gas-liquid mixing tank. Forming an enclosed space, the spiral tube being disposed within the closed space, the gate valve seat having a water inlet portion and a water outlet portion, the water inlet portion being connected to the water supply channel and the spiral tube; Communicate The spiral tube further comprises a high pressure water outlet for injecting a second gas-liquid mixed water source from the high pressure water outlet and for performing a third gas-liquid mixing in the enclosed space.

In addition, the gas-liquid mixing tank further includes a second gas inlet valve, and air is introduced second by the second gas inlet valve and performs a fourth gas-liquid mixing in the closed space.

A plurality of granular filter units are disposed in the above-described gas-liquid mixing tank and secondly filter the water source in the gas-liquid mixing tank, which filter units collide and squeeze each other to make them more durable. It allows for homogeneous gas-liquid mixing, thus raising the oxygen content of the water.

It can be seen that the advantages of the present invention are as follows: the air and water sources are simultaneously introduced into the pump, the pump pressurizing the air and water sources for mixing and once again the gas-liquid mixture is gas- The liquid may be introduced into a helical tube for mixing and then passed through a high pressure water outlet to be injected into the gas-liquid mixing tank in the form of a high pressure spray. The placement of the filter unit in cooperation with the first and second gas inlet valves allows the removal of impurities from the water and a more homogeneous mixing of the air and the water source. In addition to a significant increase in the oxygen content of the water, the mixed water source will contain a large amount of fine bubbles.

1 to 6, there are shown structures in accordance with embodiments of the present invention, which are illustrative only and are not intended to limit the scope of the present invention.

Referring to FIG. 1, a microbubble gas-liquid mixing device 1 is shown, which device is mounted and arranged in a sanitary installation 2 as shown in FIG. 5, wherein the sanitary installation 2 is one. With the above faucet 21, a water source treated by the microbubble gas-liquid mixing device 1 can be introduced into the faucet 21, the device being characterized by:

The microbubble gas-liquid mixing device 1 comprises one or more pumps 11, which have a water inlet end 111 and a water outlet end 112, the water oil inlet end ( 111 is in communication with the water outlet end 112, at least a first gas inlet valve 12 is disposed at the water inlet end 111, and the water outlet end 112 is in contact with the water supply channel 14. In communication with air introduced by the first gas inlet valve 12 and entering the pump 11 so that the pump 11 pressurizes the air and water sources to effect gas-liquid mixing for the first time and the water source A large amount of fine oxygen-containing bubbles are created in the interior, and then the gas-liquid mixture is transferred from the water outlet end 112 to the water supply channel 14. In this embodiment, the pump 11 is, for example, a high pressure pump and the first gas inlet valve 12 is a back pressure valve. As a result, the back pressure of the water source containing a lot of fine bubbles is prevented by the back pressure valve and the flow out of the first gas inlet valve 12 is prevented.

A spiral tube 13 is in communication with the water supply channel 14, the water supply channel 14 comprising a first gas-liquid mixed water source, and thus water flowing into the spiral tube 13. Can undergo a second gas-liquid mixing action. Since the air and the water source are mixed and mixed in the helical tube 13, the air can be more homogeneously mixed with the water. Oxygen-enriched water source may be conveyed from the helical tube 13.

In view of the foregoing, the microbubble gas-liquid mixing device 1 of this embodiment is directly connected to the sanitary installation 2 by a helical tube 13 that cooperates with the first gas inlet valve 12 and the pump 11. It can be connected, and the water source filled with microbubbles can be discharged, thereby achieving the effect of increasing the oxygen content in the water. The helical tube 13 can be used mounted directly to a commercial filter element (not shown).

It will be understood that the present invention still includes other modified embodiments, some of which are modified. Referring to FIG. 2, there is shown a second embodiment of the present invention, in which an adjustment valve 3 is additionally arranged in the water supply channel 14, so that water from the water supply channel 14 to the helical tube 13 is shown. The outlet water pressure from the water supply channel 14 to the helical tube 13 is adjusted while adjusting the flow capacity. In this embodiment, the regulating valve 3 is a flow-limiting valve.

Referring to FIG. 3, there is shown a third embodiment of the present invention, wherein the microbubble gas-liquid mixing device 1 further comprises a gas-liquid mixing tank 15. The gas-liquid mixing tank 15 has a gate valve seat 16 at the bottom to form a closed space 17 within the gas-liquid mixing tank 15, and the spiral tube 13 is closed. It is arranged in the space 17. In this embodiment, one end of the helical tube 13 is disposed in the gate valve seat 16, the gate valve seat 16 having a water inlet portion 161 and a water outlet portion 162. The water inlet portion 161 is in communication with the helical tube 13 and the water supply channel 14 disposed in the gate valve seat 16. The water outlet portion 162 has a diversion hole 163 in communication with the enclosed space 17 of the gas-liquid mixing tank 15.

Spiral tube 13 further includes a high pressure water outlet 18, which has a flat open end 181, as described in the foregoing embodiment, spiral tube 13. The water source is delivered from the open end 181 of the high pressure water outlet 18 after gas-liquid mixing in.

The open end 181 of the high pressure water outlet 18 is flat-shaped so that the flow channel converges along the flow direction. Thus, as the water source flows to the open end 181, the pressure will increase. As a result, the water stream is injected from the high pressure water outlet 18 in the form of a high pressure spray and impinges on one side of the closed space 17 of the gas-liquid mixing tank 15. In this embodiment, the high pressure water outlet 18 corresponds to one side of the head of the gas-liquid mixing tank 15.

In addition, the water molecules will change the direction of movement during collision with the gas-liquid mixing tank 15, and thus the direction of the high pressure water stream impinging the gas-liquid mixing tank 15 will change and the gas-liquid mixing tank Turbulent flow will occur in (15), preferably with a third gas-liquid mixing. After gas-liquid mixing, many finer bubbles will form in the water source.

In addition, in order to improve the effects of water purification and gas-liquid mixing, a plurality of granular filter units 19 are arranged in the gas-liquid mixing tank 15 to re-water the water source in the gas-liquid mixing tank 15 again. Filtering, the filter units 19 impinge on each other and squeeze each other to allow a more continuous and homogeneous gas-liquid mixing, thereby increasing the oxygen content of the water.

The three gas-liquid mixed water sources described above contain a large amount of microbubbles, that is, a large amount of air is mixed into the water source and raises the oxygen content of the water, whereby the water source is the gate valve seat 16. It can be guided to the water outlet portion 162 and drained by the switching hole 163 of the.

4 and 5, a fourth embodiment of the present invention is shown, which is different from the third embodiment described above in the following points. That is, the high pressure water outlet 18A passes through an area surrounded by the helical tube 13A, and the gas-liquid mixing tank 15 has a second gas inlet valve 151. In this embodiment, the second gas inlet valve 151 is, for example, a back pressure valve. Air is introduced a second time by the second gas inlet valve 151 and enters the closed space 17 to effect the fourth gas-liquid mixing. The oxygen content of the water will be further increased by the inflow of air through the second gas inlet valve 151.

Next, referring to FIG. 6, a fifth embodiment of the present invention is shown, which is different from the above-described fourth embodiment in the following points. That is, a manifold 31 is further provided at the water outlet end 112 such that the water stream exiting from the water outlet end 112 is directed to the water supply channel 14 and the second water supply channel 32. Flowing through the manifold 31 which distributes the water stream, the second water supply channel 32 is connected with a second gas inlet valve 151 at the top of the gas-liquid mixing tank 15. The water stream carried by the second water supply channel 32 flows through the second gas inlet valve 151 and is discharged into the gas-liquid mixing tank 15. Accordingly, the spiral tube 13A continues to spray water into the gas-liquid mixing tank 15 to gradually increase the water level, thereby closing the space 17 inside the gas-liquid mixing tank 15. The gradual reduction of will result in the compression of air in the enclosed space 17. As a result, the water stream discharged from the top of the gas-liquid mixing tank 15 will mix with the compressed air in the enclosed space 17, thereby significantly increasing the oxygen content of the water stream.

The foregoing is only related to the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Even within the spirit and scope of the present invention, various equivalent changes and modifications to the present invention may be made to the members of the present invention. Accordingly, all such equivalent changes and changes will be included in the following utility model registration claims.

From the foregoing detailed description, those skilled in the art will understand that the present invention can substantially achieve the above objects, and that the present application has been filed accordingly.

1 is a schematic view showing a structure according to a first embodiment of the present invention.

2 is a schematic view showing a structure according to a second embodiment of the present invention.

3 is a schematic view showing a structure according to a third embodiment of the present invention.

4 is a schematic view showing a structure according to a fourth embodiment of the present invention.

5 is a schematic diagram illustrating a service state according to a fourth embodiment of the present invention.

6 is a schematic diagram illustrating a service state according to a fifth embodiment of the present invention.

7 is a schematic view showing a conventional microbubble water treatment apparatus.

Claims (16)

A microbubble gas-liquid mixing device mounted and disposed in a sanitary installation, wherein the sanitary installation includes one or more faucets, into which the water source treated by the microbubble gas-liquid mixing device is introduced into the faucet. In a gas-liquid mixing device: The microbubble gas-liquid mixing device comprises one or more pumps and a helical tube; The pump has a water inlet end and a water outlet end, the water inlet end communicates with the water outlet end, at least a first gas inlet valve is disposed at the water inlet end, and the water outlet end is a water supply channel. In which air is introduced by the first gas inlet valve and into the pump such that the pump pressurizes the air and water source for gas-liquid mixing and then transfers the mixture from the water outlet end to the water supply channel, The air and water sources are swirled in the spiral tube by the spiral tube communicating with the water supply channel such that the gas-liquid mixed water source contained in the water supply channel flows into the spiral tube and once again gas-liquid mixed. Microbubble gas-liquid mixing device, characterized in that it allows mixing and allows oxygen-enriched water sources to be discharged from the spiral tube. The method of claim 1, Microbubble gas-liquid mixing device, characterized in that the pump is a high pressure pump. The method of claim 1, And the first gas inlet valve is a back pressure valve. The method of claim 1, An adjustment valve is additionally arranged in the water supply channel to adjust the water flow capacity from the water supply channel to the spiral tube while simultaneously adjusting the outlet water pressure from the water supply channel to the spiral tube. Bubble gas-liquid mixing device. The method of claim 4, wherein Microbubble gas-liquid mixing device, characterized in that the control valve is a flow-limiting valve. The method of claim 1, The microbubble gas-liquid mixing device is further provided with a gas-liquid mixing tank, The gas-liquid mixing tank has a gate valve seat to form a closed space in the gas-liquid mixing tank, the spiral tube is disposed in the closed space, and the gate valve seat has a water inlet portion and a water outlet portion. Wherein said water inlet portion is in communication with said water supply channel and said helical tube. The method of claim 6, And the gate valve seat is disposed at the bottom of the gas-liquid mixing tank. The method of claim 6, One end of the helical tube is disposed on the gate valve seat. The method of claim 6, And the gate valve seat has a switching hole in communication with a closed space of the gas-liquid mixing tank. The method of claim 1, The spiral tube further includes a high pressure water outlet, And the high pressure water outlet has a flat open end to deliver a water source from the open end of the high pressure water outlet of the helical tube. The method of claim 6, The spiral tube further includes a high pressure water outlet, And the high pressure water outlet has a flat open end to deliver a water source from the open end of the high pressure water outlet of the helical tube. The method of claim 11, And the high pressure water outlet corresponds to one side of the head of the gas-liquid mixing tank. The method of claim 6, The gas-liquid mixing tank further includes a second gas inlet valve, Air is introduced a second time by the second gas inlet valve and is introduced into the closed space for gas-liquid mixing. The method of claim 13, And the second gas inlet valve is a back pressure valve. The method of claim 6, Multiple granular filter units are disposed in the gas-liquid mixing tank to once again filter the water source in the gas-liquid mixing tank, The filter unit collides and compresses with each other to allow more continuous and homogeneous gas-liquid mixing, thereby increasing the oxygen content of the water. The method of claim 13, The microbubble gas-liquid mixing device additionally includes a manifold, whereby the water stream exiting the water outlet end flows through the manifold that distributes the water stream to the water supply channel and the second water supply channel. And the second water supply channel is connected to a second gas inlet valve of the gas-liquid mixing tank.

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