TWI690494B - Hydrogen-oxygen ultra-micro bubble device - Google Patents

Abstract

This creation is a hydrogen-oxygen ultrafine bubble device, which includes a storage unit, an ultrafine bubble making unit and a uniform pressure mixing unit, the storage unit includes a bracket, a storage tank, a bifurcated tube and an air inlet tube, The storage tank is set on the bracket, the branch pipe is connected to the storage tank and bypasses the trachea. The ultra-fine bubble making unit is set on the bracket and contains the second reverse osmosis pump set, which is connected to the branch pipe respectively, and the pressure is evenly mixed The unit is installed on a bracket and connected to the two reverse osmosis pumps and storage tanks and contains most magnesium particles. The original hydrogen and oxygen ultra-micro bubble device uses the reverse osmosis pump to compress and burst hydrogen and oxygen into ultra-micro bubbles with a diameter of 0.2 microns. It can kill a 0.2 micron mixture, and the magnesium particles chemically react with hydrogen, which is bacteriostatic and sterilized, with sterilization practicality and functional diversity.

Description

Hydrogen-oxygen ultra-micro bubble device

This creation is a hydrogen-oxygen ultrafine bubble device, especially a hydrogen-oxygen ultrafine bubble device for preparing ultrafine bubbles to achieve good sterilization effect.

Microbubble is a kind of bubbles with a small diameter. Common microbubble devices on the market can usually produce bubbles with a diameter of about 50 microns. After the microbubbles manufactured by the microbubble device are injected into water, the diameter of the bubbles is micrometers. The time that bubbles stay in water is longer than that of bubbles with a diameter of millimeters. Micro-bubbles stay longer in water, so the water will appear turbid white. When the water with micro-bubbles passes through the rupture and disintegration of micro-bubbles The energy emitted can make the mixture of microorganisms, bacteria or pollutants in the water destroyed by the destruction of micro bubbles. The energy emitted by the disintegration of micro bubbles can be physically harmed to achieve physical sterilization. Bubble water has been used in industries such as agricultural irrigation, fish farming, or food processing.

The existing micro-bubble device conveys the water of mixed air by an impeller pump. The impeller pump includes a pump casing and a blade. The pump casing has a rotating space, a water inlet, an air inlet, and an outlet. A rotating space is formed inside the pump housing, the water inlet is formed in the pump housing and communicates with the rotating space, the air inlet is formed in the pump housing and communicates with the water inlet, and the outlet is formed in the pump housing and communicates with the rotating space The vane is rotatably provided in the rotating space of the pump casing. During the transportation process, the water input from the water inlet and the air input from the air inlet allow the blades of the impeller pump to rotate and strike, so that the hydrogen in the water And the oxygen is struck by the blade and the air is crushed, thereby generating fine bubbles.

However, the blade blow of the impeller pump of the existing micro-bubble device can produce bubbles with a diameter of about 50 microns. The bubbles produced by the micro-bubble device maintain the size of the micron diameter and cannot kill smaller than 50 microns. Microorganisms, so the effectiveness of the micro-bubble device is currently limited in the elimination of bacteria, and in the process of making micro-bubbles, the air input by the air inlet is general air, whether it is in agricultural irrigation, fish farming or food processing None of them have any innovative effects, causing the problem of insufficient functionality of the micro-bubble device.

The main purpose of this creation is to provide a hydrogen-oxygen ultra-micro bubble device, to improve the existing micro bubble device can only produce micro bubbles with a diameter of about 50 microns, can not eliminate microbes smaller than 50 microns, resulting in the problem of poor sterilization effect And, the micro-bubble is made of general air, and has no additional effect, which causes the problem of insufficient functionality of the micro-bubble device.

To achieve the above-mentioned purpose, the oxyhydrogen ultra-micro bubble device includes: a storage unit including a bracket, a storage tank, a bifurcated tube, a gas flow meter and an air inlet tube, the storage tank is located in On the bracket, the branch pipe communicates with the storage tank and branches into two water inlet pipes, the gas flow meter is provided on the bracket, the gas inlet pipe is provided on the bracket and flows through the gas flow meter and communicates with the branch pipe, The diameter of the air inlet pipe is smaller than the diameter of the bifurcated pipe; an ultrafine bubble making unit, the ultrafine bubble making unit is provided on the holder of the storage unit, the ultrafine bubble making unit includes a two reverse osmosis pump And a combined pipe, the two reverse osmosis pumps are respectively connected to the two inlet pipes of the bifurcated pipe, the two reverse osmosis pumps are respectively connected to the combined pipe; and a uniform pressure mixing unit, the uniform pressure mixing unit is provided in the A bracket is connected to the merging tube. The uniform pressure mixing unit includes a mixing barrel, a plurality of magnesium particles and a circulation tube. The mixing barrel is provided on the bracket and connected to the merging tube. The majority of magnesium particles are placed inside the mixing barrel The circulation pipe is connected to the mixing barrel and extends into the storage tank. The storage unit, the ultra-micro bubble making unit and the uniform pressure mixing unit form a circulation system.

The hydrogen-oxygen ultrafine air bubble device uses the reverse osmosis pump unit made of the ultrafine air bubble, the water from the storage tank flows into the ultrafine air bubble before the unit is made, the air inlet pipe will input air to make the water mixed with air When the water containing air is sent to the second water inlet pipe and enters the second reverse osmosis pump unit, the second reverse osmosis pump unit reduces the hydrogen and oxygen in the water to compress and rupture to become fine bubbles, and the storage unit and the ultra-micro bubbles The manufacturing unit and the uniform pressure mixing unit form a circulation system, allowing the hydrogen and oxygen in the water to compress and rupture to form ultra-micro bubbles with a diameter of 0.2 microns, which can kill a mixture of microorganisms, bacteria or pollutants with a size of 0.2 microns in the water. And the hydrogen produced by the chemical reaction of the majority of magnesium particles allows the ultra-fine bubbles of hydrogen to achieve the effects of bacteriostasis and sterilization, to achieve the practicality of sterilization and enhance the diversity of functions.

As shown in FIG. 1, it is disclosed a preferred embodiment of the device for creating ultrafine bubbles of oxyhydrogen. As can be seen from the drawings, the device for creating ultrafine bubbles of oxyhydrogen includes a storage unit 10 and a unit 20 for making ultrafine bubbles And a pressure uniform mixing unit 30.

As shown in FIGS. 1 to 3, the storage unit 10 includes a bracket 11, a storage tank 12, a branch pipe 13, a gas flow meter 14 and an air inlet pipe 15. The storage tank 12 is provided on the bracket 11 , The branch pipe 13 communicates with the storage tank 12 and branches into two water inlet pipes 16, the gas flow meter 14 is provided on the bracket 11, and the gas inlet pipe 15 is provided on the bracket 11 and flows through the gas flow meter 14 and communicates The branch pipe 13 and the air inlet pipe 15 have a smaller diameter than the branch pipe 13. The storage unit 10 includes an air pump 17 and a filter 18. The air pump 17 is disposed on the bracket 11 and connected to the air inlet pipe 15 and the storage tank 12, the filter 18 is provided on the bracket 11, the branch pipe 13 circulates the filter 18 and branches out of the two water inlet pipes 16 behind the filter 18, further, The storage tank 12 has a filling tube 121 and a completion tube 122. The filling tube 121 and the completion tube 122 are both provided in the storage tank 12 and communicate with the storage tank 12.

As shown in FIGS. 1 and 2, the ultra-micro-bubble forming unit 20 is provided on the holder 11 of the storage unit 10. The ultra-micro-bubble forming unit 20 includes two reverse osmosis pump sets 21 and a combined tube 22. The reverse osmosis pump group 21 is respectively connected to the two water inlet pipes 16 of the bifurcated pipe 13, and the second reverse osmosis pump group 21 is respectively connected to the combined pipe 22, wherein each reverse osmosis pump group 21 includes a first reverse osmosis pump 23 and A second reverse osmosis pump 24, the two first reverse osmosis pumps 23 are respectively connected to the two water inlet pipes 16 of the branch pipe 13, the two first reverse osmosis pumps 23 are respectively connected to the two second reverse osmosis pumps 24, so that each A first reverse osmosis pump 23 is connected in series with the corresponding second reverse osmosis pump 24, and the two second reverse osmosis pumps 24 are respectively connected to the merger pipe 22.

As shown in FIGS. 1 to 3, the uniform pressure mixing unit 30 is disposed on the bracket 11 and connected to the combining tube 22. The uniform pressure mixing unit 30 includes a mixing barrel 31, a plurality of magnesium particles 32 and a circulation tube 33, The mixing barrel 31 is disposed on the bracket 11 and connected to the merger tube 22, the majority of magnesium particles 32 are placed inside the mixing barrel 31, the circulation tube 33 is connected to the mixing barrel 31 and extends into the storage tank 12, the storage unit 10. The ultra-micro bubble making unit 20 and the uniform pressure mixing unit 30 form a circulation system.

Further, as shown in FIG. 1, the oxyhydrogen ultra-micro bubble device includes a cooling unit 40 including a refrigerant coil 41, a temperature insulating layer 42 and a cooler 43. The refrigerant coil 41 is provided in Outside the storage tank 12, the refrigerant coil 41 controls the temperature of the storage tank 12 to be between 10° C. and 20° C. The temperature barrier 42 is provided outside the cold coal coil, and the temperature barrier 42 maintains the refrigerant The temperature regulated by the coil 41, the cooler 43 is connected to the refrigerant coil 41.

As shown in FIG. 1 to FIG. 3, it is disclosed that a preferred embodiment of the device for creating ultra-hydrogen-oxygen bubbles, the user can fill the filling tube 121 of the storage tank 12 with water 50 to fill the storage tank 12 Water 50, and then start the operation of producing ultra-hydrogen and oxygen bubbles, the water 50 in the storage tank 12 will flow from the branch pipe 13 through the filter 18, when passing the filter 18 impurities in the water 50 Clear to ensure that the ultra-bubbles making unit 20 will not damage the second reverse osmosis pump unit 21, and then water 50 will flow from the branch pipe 13 into the second water inlet pipe 16 and enter the second reverse osmosis Pump set 21, at the same time, air will flow into the air inlet pipe 15 and pass through the gas flow meter 14, the user can control the flow rate of the air in the air inlet pipe 15 by controlling the gas flow meter 14, the air will flow from the air inlet pipe 15 flows into the branch pipe 13, because the diameter of the air inlet pipe 15 is smaller than the diameter of the branch pipe 13, according to the Burke effort theorem, it can be known that air will be carried by the water 50 to the two water inlet pipes 16.

In the above, the water 50 with air will enter the second reverse osmosis pump unit 21 of the ultra-micro-bubble making unit 20, the water 50 with air will pass through the first reverse osmosis pump 23, and the water 50 will be subjected to the first The pressurization of the reverse osmosis pump 23 causes the air in the water 50 to be compressed and rupture and reduce to fine bubbles. Then the water 50 is pressurized and sent to the second reverse osmosis pump 24, and the air in the water 50 is subjected to the first The pressure of the second reverse osmosis pump 24 ruptures and reduces to become finer bubbles. The first reverse osmosis pump 23 and the second reverse osmosis pump 24 form a series, which can make the air in the water 50 more pressurized. , The compressed air rupture is reduced to become fine bubbles, the effect is better, the water 50 and fine bubbles pressurized by the second reverse osmosis pump group 21 are sent from the combining pipe 22 into the uniform pressure mixing unit 30, the water 50 and fine bubbles enter In the mixing barrel 31, most of the magnesium particles 32 in the mixing barrel 31 meet water 50, and a chemical reaction will generate hydrogen gas through the activity, and the water 50 and fine air bubbles will be squeezed by the uniform pressure in the mixing barrel 31, thereby generating mixing The liquid containing microbubbles of hydrogen and microbubbles of oxygen uniformly, and then the liquid containing microbubbles of hydrogen and microbubbles is transported back to the storage tank 12 through the circulation tube 33, and the above steps are circulated for 5 minutes to produce a diameter As ultrafine bubbles of 0.2 micron (μm) hydrogen and oxygen, the cooling unit 40 can maintain the ultrafine bubbles content in the storage tank 12.

In the above, after the hydrogen-oxygen ultrafine bubble device circulates the above-mentioned operation steps for 5 minutes, the ultrafine bubble liquid with a diameter of 0.2 microns of hydrogen and oxygen will be stored in the storage tank 12, and the user can use the completion tube 122 to obtain the ultrafine bubbles The liquid can be used in agricultural irrigation, fish farming or food processing industries. Because the diameter of the ultra-micro bubbles is 0.2 microns, the energy emitted by the ultra-micro bubbles when they disintegrate can kill 0.2 microns of microorganisms, bacteria or For the mixture of pollutants and the like, the energy emitted by the disintegration of ultrafine bubbles can be physically harmed to achieve physical sterilization, and the hydrogen produced by the chemical reaction of the majority of magnesium particles 32 makes the gas of ultrafine bubbles have both oxygen and hydrogen. In terms of use function, the ultrafine gas bubbles of hydrogen will produce supersonic phenomenon when the ultrafine gas disintegrates, and has the characteristics of negative ions, so as to achieve the effect of bacteriostasis and sterilization, to achieve the practicality of sterilization and enhance the diversity of functions.

To sum up, the original hydrogen-oxygen ultrafine bubble device uses the ultrafine bubbles to make the reverse osmosis pump unit 21 of the unit 20, and the water 50 containing air is sent from the branch pipe 13 into the two water inlet pipes 16 and When entering the reverse osmosis pump group 21, the reverse osmosis pump group 21 reduces the air compression and rupture in the water 50 to become fine bubbles, and the storage unit 10, the ultra-micro bubble making unit 20 and the pressure are uniformly mixed Unit 30 forms a circulation system, which allows oxygen and hydrogen to rupture in the circulation and reduce the formation of ultra-micro bubbles with a diameter of 0.2 microns, which can kill 0.2 micron-sized microorganisms, bacteria, or contaminants in water 50. The hydrogen produced by the chemical reaction of the magnesium particles 32 allows the ultrafine bubbles of hydrogen to achieve the effect of bacteriostasis and sterilization, to achieve the practicality of sterilization and enhance the diversity of functions.

10 11 storage unit 12 storage tank holder 121 to complete the fill tube 122 the branch pipe 14 a gas pipe 13 into the pipe 16 flow meter 15 water inlet pipe 17 of air pump 18 filter 20 made of ultrafine bubble pump unit 21 of the reverse osmosis were combined 22 a first mixing pipe 23 of the reverse osmosis unit 24 of the second reverse osmosis pump 30 pumps pressure uniformly mixing tub 31 33 32 Mg granules circulating pipe 40 of the cooling unit 41 the refrigerant coil 42 for insulation layer 43 water cooler 50

Figure 1: A schematic side view of one of the preferred embodiments of the oxyhydrogen ultrafine bubble device. FIG. 2 is a schematic side view of the operation mode of a preferred embodiment of the hydrogen-oxygen ultrafine bubble device. Fig. 3: A partially enlarged schematic side view of the operation mode of a preferred embodiment of the oxyhydrogen ultrafine bubble device.

10 11 storage unit 12 storage tank holder 121 to complete the fill tube 122 the branch pipe 14 a gas pipe 13 into the pipe 16 flow meter 15 water inlet pipe 17 of air pump 18 filter 20 made of ultrafine bubble pump unit 21 of the reverse osmosis were combined 22 mixing the first reverse osmosis unit 23 pipe 24 pump 30 second pump pressure reverse osmosis uniformly mixing tub 31 40 32 Mg granules refrigerant cooling coil unit 41 cooler 42 separator 43 stratosphere

Claims (7)

A hydrogen-oxygen ultra-micro bubble device includes: a storage unit including a bracket, a storage tank, a bifurcated tube, a gas flow meter and an air inlet tube, the storage tank is provided on the bracket, the The bifurcating pipe communicates with the storage tank and bifurcates into two water inlet pipes. The gas flow meter is provided on the bracket. The gas inlet pipe is provided on the bracket and flows through the gas flow meter and communicates with the bifurcation pipe. The diameter is smaller than the diameter of the bifurcated tube; an ultra-micro bubble making unit, the ultra-micro bubble making unit is provided on the support of the storage unit, the ultra-micro bubble making unit includes two reverse osmosis pump sets and a combined tube , The two reverse osmosis pump sets are respectively connected to the two inlet pipes of the bifurcated pipe, the two reverse osmosis pump sets are respectively connected to the combining pipe; and a uniform pressure mixing unit, the uniform pressure mixing unit is provided on the bracket and connected to the merger The tube, the uniform pressure mixing unit includes a mixing barrel, a plurality of magnesium particles and a circulation tube, the mixing barrel is provided on the bracket and connected to the combining tube, the majority of magnesium particles are placed inside the mixing barrel, the circulation tube is connected The mixing barrel extends into the storage tank, and the storage unit, the ultra-micro bubble making unit and the uniform pressure mixing unit form a circulation system. The hydrogen-oxygen ultrafine bubble device according to claim 1, wherein each reverse osmosis pump set includes a first reverse osmosis pump and a second reverse osmosis pump, and the two first reverse osmosis pumps are respectively connected to the branch pipes Two water inlet pipes, the two first reverse osmosis pumps are respectively connected to the two second reverse osmosis pumps, so that each first reverse osmosis pump is connected in series with the corresponding second reverse osmosis pump, and the two second reverse osmosis pumps Connect the merged tubes separately. The hydrogen-oxygen ultrafine bubble device according to claim 1, wherein the storage unit includes an air pump, the air pump is provided on the bracket and connected to the air inlet pipe and the storage tank. The hydrogen-oxygen ultrafine bubble device according to claim 2, wherein the storage unit includes an air pump, the air pump is provided on the bracket and connected to the air inlet pipe and the storage tank. The oxyhydrogen ultrafine bubble device according to any one of claims 1 to 4, wherein the oxyhydrogen ultrafine bubble device includes a cooling unit including a refrigerant coil, a temperature insulating layer, and a cooling unit Machine, the refrigerant coil is arranged outside the storage tank, the temperature barrier is arranged outside the cold coal coil, and the cooling machine is connected to the refrigerant coil. The oxyhydrogen ultrafine bubble device according to any one of claims 1 to 4, wherein the storage unit includes a filter, the filter is provided on the holder, and the branch pipe flows through the filter and passes through the filter The rear of the branch bifurcates out of the two inlet pipes. The hydrogen-oxygen ultrafine bubble device according to claim 5, wherein the storage unit includes a filter, the filter is disposed on the bracket, the branch pipe circulates the filter and branches out two behind the filter Into the water pipe.

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