JP6351044B2 - Infusion generator - Google Patents

Description

The present invention relates to liquid medicine transfusion generation equipment that can be sent directly to the diseased cells.

There are two types of cancer treatment by infusion: systemic chemotherapy and local chemotherapy, and an effective treatment method is selected depending on the condition of the cancer.
Systemic chemotherapy is a treatment in which an infusion is made throughout the body by intravenous infusion. Therefore, since the infusion reaches not only the primary lesion but also the metastatic lesion and lesion, a wide range of treatment can be performed. However, since the infusion is diluted with blood when it travels around the whole body, there is a disadvantage that the effect becomes small.
Local chemotherapy is a treatment mainly performed when enlarged tumors such as hepatocellular carcinoma remain locally and there are still few metastases. In local chemotherapy, the catheter is inserted to advance to the vicinity of the lesion, and the infusion solution is injected to the lesion at the shortest distance, so the dose of the drug solution can be reduced and the amount of entry into normal cells can be reduced. . Thus, local chemotherapy can reduce side effects. In addition, if there is metastasis, after tumor reduction, switch to systemic chemotherapy and treat the primary and metastatic lesions, leading to complete cure.

  In catheter treatment, a drug-eluting embolic material that blocks a feeding artery, cuts off nutrition to cancer and creates an ischemic state, is intensively delivered into the tumor by a catheter over several hours or days. It is a treatment that is effective even in places where surgery is not possible or metastasis.

  Thus, although it is an infusion used for a treatment, what was indicated in patent documents 1 is known about an infusion. It is described that the infusion solution of Patent Document 1 contains oxygen nanobubbles in an ultrafine state. In this infusion solution, the diameter of nanobubbles is in the range of 1 to 1000 nm, and the salt content is 0.01 to 3.5% by weight.

JP 2011-1271 A

The infusion of Patent Document 1 is a surgical operation based on a whole body or a local ultra-hyperthermia method, a craniotomy operation based on a selective cooling method of the brain, a cerebral cryotherapy based on a selective cooling method of the brain, such as stroke (particularly cerebral infarction) It is described that it is used for treatment of damage, treatment of peripheral circulatory insufficiency, and activation of peripheral cells / tissue whose activity is reduced by peripheral circulatory failure.
In cancer treatment, there is a need for an infusion that can provide effective treatment.

Accordingly, the present invention aims at providing an infusion product equipment capable of generating a infusion having an excellent therapeutic effect.

  The infusion generation device of the present invention is an electrolyzed water generating unit that generates acidic water and alkaline water from raw water, and fine bubble acidic water in which hydrogen nanobubbles and a chemical solution are mixed in acidic water fed from the electrolyzed water generating unit, Or the nanobubble mixing unit which produces | generates either the fine bubble alkaline water by which the hydrogen nanobubble was mixed with the alkaline water sent from the said electrolyzed water production | generation unit, or both as an infusion solution was provided.

According to the present invention, fine bubble acidic water in which hydrogen nanobubbles and a chemical solution are mixed in acidic water has high permeability and a negative potential, and therefore is attracted to a lesion that has a positive potential. Can enter the entrance to the cell. In addition, fine-bubble alkaline water containing hydrogen nanobubbles flows in the blood, so that deposits such as lipid and corsterol attached to the inner wall of the blood vessel can be decomposed and removed from the blood vessel.
Further, by circulating the fine bubble acidic water and the fine bubble alkaline water between the fine bubble mixer and the tank, the concentration of nanobubbles can be increased and the bubble size can be further refined.

In the infusion generation device of the present invention, it is desirable that the nanobubble mixing unit generates an infusion in which carbon dioxide gas is further mixed as a mixed gas in the alkaline water.
Alkaline water containing carbonic acid nanobubbles can adsorb and discharge waste products dissolved in blood, and promote blood circulation, so that the blood circulation state can be improved.

The nanobubble mixing unit may generate an infusion solution in which oxygen gas and nutrients are further mixed as a mixed gas in the alkaline water.
The enzyme in the blood can be activated because the nutrient of the enzyme in the blood is mixed with the fine-bubble alkaline water containing the oxygen nanobubbles.

The nanobubble mixing unit includes a fine bubble mixer that mixes nanobubbles with acid water and alkaline water to form fine bubble acidic water and fine bubble alkaline water, and fine bubble acidic water and fine bubbles from the fine bubble mixer. It is desirable to have a tank for storing the bubble alkaline water and a pipe for circulating the fine bubble acidic water and the fine bubble alkaline water between the fine bubble mixer and the tank.
By circulating the fine bubble acidic water and fine bubble alkaline water between the fine bubble mixer and the tank, the concentration of nanobubbles can be increased and the bubble size can be further refined.

  According to the present invention, hydrogen nanobubbles enter the entrance to the diseased cells, and the drug solution is released into the tumor. Therefore, an optimal drug-eluting embolic material can be obtained, so that an infusion solution having an excellent therapeutic effect can be obtained. Can be generated.

It is a figure which shows the structure of the infusion production | generation apparatus which concerns on embodiment of this invention. It is a figure for demonstrating the structure of the electrolysis production | generation unit of the infusion production | generation apparatus shown in FIG. It is a figure for demonstrating the structure of the nano bubble mixing unit of the infusion production | generation apparatus shown in FIG. It is a figure for demonstrating the state of the infusion in blood. It is a figure for demonstrating the state which inject | poured the infusion solution to the patient by infusion. It is a figure for demonstrating the state which inject | poured the infusion solution to the patient with the catheter.

An infusion generation device according to an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, an infusion generating device 10 according to an embodiment of the present invention generates an infusion that is administered by infusion, catheter, or intravenous injection. The infusion generation device 10 includes an electrolyzed water generation unit 20 and a nanobubble mixing unit 30. The electrolyzed water generation unit 20 and the nanobubble mixing unit 30 are connected to each other by couplers C1 and C2 formed at the tips of the hoses H1 and H2 and the nanobubble mixing unit 30.

The electrolyzed water generation unit 20 generates acid water and alkaline water using pure water as raw water, and sends the water to the nanobubble mixing unit 30.
As shown in FIG. 2, the electrolyzed water generation unit 20 includes a pure water tank 21 that stores pure water that does not contain impurities or is less used as raw water. The pure water tank 21 is connected to a pump P21 that pumps pure water stored in the pure water tank 21 and supplies the pure water to the filter 22. The filter 22 is connected to an electrolyzed water generator 23 that electrolyzes pure water into acidic water and alkaline water. Between the filter 22 and the electrolyzed water generating unit 23, an adjustment valve V21 for adjusting the addition of sodium chloride is connected.

  The electrolyzed water generation unit 23 is connected to an acidic water tank 24 that stores acidic water and an alkaline water tank 25 that stores alkaline water. Hose H <b> 1 and H <b> 2 are connected to the acidic water tank 24 and the alkaline water tank 25.

  As shown in FIG. 3, the nanobubble mixing unit 30 mixes nanobubbles with acidic water and alkaline water sent from the electrolyzed water generation unit 20, and also mixes chemicals, nutrients, and the like to produce fine bubble acidic water and fine bubble alkaline. Water is generated, and microbubble mixed electrolyzed water obtained by mixing the microbubble acidic water and the microbubble alkaline water is produced as an infusion solution.

  In the nanobubble mixing unit 30, a first microbubble mixer 301 (microbubble mixer) that mixes acidic water from the electrolyzed water generating unit 20 and microbubbles is connected via an automatic three-way valve V31. Moreover, the 2nd micro bubble mixer 302 (micro bubble mixer) which mixes the alkaline water and the micro nano bubble from the electrolyzed water production | generation unit 20 is connected via the automatic three-way valve V32.

  The first microbubble mixer 301 includes a first gas-liquid mixer 301a that mixes hydrogen gas, oxygen gas, or carbon dioxide gas into a microbubble as a mixed gas and mixes it with acidic water, and mixes a chemical with acidic water. A first pump 301b that pumps acidic water mixed with bubbles and a first micronizer 301c that reduces bubbles of hydrogen gas mixed in acidic water to the size of nanobubbles are provided.

  The second microbubble mixer 302 converts hydrogen gas into microbubbles and mixes it with alkaline water, and pumps the alkaline water mixed with microbubbles with the second gas-liquid mixer 302a that mixes chemicals and nutrients. A second pump 302b and a second micronizer 302c for reducing bubbles of hydrogen gas mixed in alkaline water to the size of nanobubbles are provided.

  A water injection side of an acidic water storage tank 303 (tank) is connected to the first micronizer 301c. Furthermore, the water intake side of the acidic water storage tank 303 is connected to the automatic three-way valve V31, so that the first fine bubble mixer 301, the acidic water storage tank 303, the automatic three-way valve V31, and the pipe connecting the same. Thus, a circulation path is formed.

  A water injection side of an alkaline water storage tank 304 (tank) is connected to the second micronizer 302c. Furthermore, since the water intake side of the alkaline water storage tank 304 is connected to the automatic three-way valve V32, the second fine bubble mixer 302, the alkaline water storage tank 304, the automatic three-way valve V32, and a pipe connecting them. Thus, a circulation path is formed.

  An electrolysis unit 305 that generates hydrogen gas by electrolysis is connected to the first gas-liquid mixer 301a via an automatic valve V33. The first gas-liquid mixer 301a is connected to a chemical solution charging unit 306 for adding a chemical solution. As the drug solution, a conventional drug solution used for systemic chemotherapy or local chemotherapy can be used.

  An electrolysis unit 305 is connected to the second gas-liquid mixer 302a via an automatic valve V33 that allows hydrogen gas to flow in and off, and an automatic valve V34 that allows oxygen gas to flow in and off. Yes. In addition, a carbon dioxide cartridge 307 for supplying carbon dioxide via an automatic valve V35 is connected to the second gas-liquid mixer 302a. In addition, a chemical liquid charging unit 306 for adding a chemical liquid is also connected to the second gas-liquid mixer 302a. Furthermore, a nutrient input unit 308 for adding nutrients for enzymes such as magnesium is connected to the second gas-liquid mixer 302a.

An acidic water storage unit 310 is connected to the acidic water storage tank 303 via a first sterilization unit 309 that kills microorganisms. The alkaline water storage tank 304 is connected to an alkaline water storage unit 312 via a second sterilization unit 311 that kills microorganisms.
The acidic water storage unit 310 and the alkaline water storage unit 312 are connected to a pump P31 for drawing fine bubble acidic water from the acidic water storage tank 303 and drawing fine bubble alkaline water from the alkaline water storage tank 304. .

  The water intake side of the acidic water storage unit 310 and the water intake side of the alkaline water storage unit 312 are connected by a junction 313 of a pipe formed in a Y shape via regulating valves V36 and V37. And the junction part 313 is connected to the connection part 314 for connecting with the exterior, when using a drip and a catheter via the adjustment valve V38.

  The opening / closing and closing of the regulating valve V21 of the electrolyzed water generating unit 20 shown in FIG. 2 and the starting and stopping of the pump P11 are controlled by the control unit 26 built in the electrolyzed water generating unit 20. Further, the automatic three-way valves V31 and V32, the automatic valves V33 to V35 and the regulating valves V36 to V38 of the nano bubble mixing unit 30 shown in FIG. 3 are opened / closed and switched, and the first pump 301b, the second pump 302b and the pump P31 are switched. The starting and stopping are controlled by a control unit 315 built in the nanobubble mixing unit 30.

  By adjusting the control valve V36 connected to the water intake side of the acidic water storage unit 310 and the control valve V37 connected to the water intake side of the alkaline water storage unit 312 under the control of the control unit 315, the acidic water storage unit 310 is adjusted. Water can be fed to the connecting portion 314 by using only fine-bubble acidic water from the side, only fine-bubble alkaline water from the alkaline water storage unit 312, or changing the mixing ratio.

The operation and use state of the infusion generation device 10 according to the embodiment of the present invention configured as described above will be described with reference to the drawings.
When the infusion generation device 10 shown in FIG. 1 is started, first, the pump P11 pumps pure water as raw water from the pure water tank 21. The pure water removes impurities such as slight metals and microorganisms contained in the pure water by the filter 22. And the sodium chloride which is the quantity of electrolyte adjusted with the regulating valve V21 is added to a pure water.

  Then, the electrolyzed water generator 23 generates acidic water and alkaline water based on pure water to which sodium chloride is added, the acidic water is stored in the acidic water tank 24, and the alkaline water is the alkaline water tank 25. It is stored in.

  The acidic water stored in the acidic water tank 24 is introduced into the nanobubble mixing unit 30 via the hose H1, and the alkaline water stored in the alkaline water tank 25 is introduced into the nanobubble mixing unit 30 via the hose H2.

In the nanobubble mixing unit 30, first, the acidic water is sent to the first gas-liquid mixer 301a of the first fine bubble mixer 301 via the automatic three-way valve V31.
In the first gas-liquid mixer 301a, the electrolysis unit 305 converts the hydrogen gas obtained by electrolysis into microbubbles and mixes it with acidic water. At this time, the chemical solution from the chemical solution input unit 306 is also converted into the first gas-liquid mixer 301a.
Then, the acidic water in which the hydrogen gas and the chemical liquid are mixed is pumped by the first pump 301b, the first micronizer 301c reduces the bubbles of the hydrogen gas to the size of the nanobubbles, and the acidic water is converted into the fine bubble acidic water. To do. The fine bubble acidic water from the first micronizer 301 c is stored in the acidic water storage tank 303.

  Next, the fine bubble acidic water from the acidic water storage tank 303 is fed again to the first gas-liquid mixer 301a via the automatic three-way valve V31, so that the hydrogen gas is mixed, and the first pump 301b The bubble size is further refined by the first micronizer 301c by water supply. Then, the fine bubble acidic water from the first micronizer 301 c returns to the acidic water storage tank 303.

  In this way, the fine bubble acidic water is circulated by piping connecting the first fine bubble mixer 301, the acidic water storage tank 303, and the automatic three-way valve V31 in order, thereby increasing the concentration of nanobubbles, The bubble size can be further refined.

  Similarly, the alkaline water from the electrolyzed water generation unit 20 is similar to the automatic three-way valve V32, hydrogen gas or oxygen gas supplied from the electrolysis unit 305, carbon dioxide supplied from the carbon dioxide cartridge 307, chemicals, nutrients, and the like. Are mixed with alkaline water, and the second fine bubble mixer 302 is made into fine bubble alkaline water in which bubbles are refined, and the alkaline water storage tank 304 for storing fine bubble alkaline water is connected to the fine water by a pipe in order. By circulating the bubble alkaline water, the concentration of nanobubbles can be increased and the bubble size can be further refined. In this embodiment, the chemical solution is mixed only with acidic water, and the nanobubble mixing unit 30 can mix the chemical solution with alkaline water. However, as an infusion to be administered to a patient, the chemical solution is mixed with alkaline water. Not.

  The fine bubble acidic water stored in the acidic water storage tank 303 and the fine bubble alkaline water stored in the alkaline water storage tank 304 are sucked into the acidic water storage unit 310 and the alkaline water storage unit 312 by the pump P31. The negative water pressure is taken from the acidic water storage tank 303 and the alkaline water storage tank 304 and poured into the acidic water storage unit 310 and the alkaline water storage unit 312.

The fine bubble acidic water injected into the acidic water storage unit 310 and the fine bubble alkaline water injected into the alkaline water storage unit 312 are mixed by the confluence unit 313 in amounts adjusted by the regulating valves V36 and V37. Then, microbubble mixed electrolyzed water is generated.
The fine bubble mixed electrolyzed water from the merging portion 313 is adjusted by the regulating valve V38 and is sent from the connecting portion 314 to the outside as an infusion.

Thus, in the nanobubble mixing unit 30, hydrogen gas and chemical liquid can be selectively mixed with acidic water, and hydrogen gas, oxygen gas, and carbon dioxide gas can be selectively mixed with alkaline water.
Further, in the nanobubble mixing unit 30, either fine bubble acidic water containing nanobubbles in acidic water or fine bubble alkaline water containing nanobubbles in alkaline water, or both can be mixed. .
In addition, the control unit 315 controls the nutrient input unit 308 to appropriately add nutrients to the alkaline water.

In the present embodiment, as an infusion, the control unit 315 controls the automatic valve and the regulating valve to generate the following four types of fine bubble acidic water and fine bubble alkaline water.
For example, infusion solutions are (1) fine bubble acidic water in which hydrogen nanobubbles and chemicals are mixed in acidic water, (2) fine bubble acidic water in which hydrogen nanobubbles are mixed in alkaline water, and (3) carbonic acid nanobubbles in alkaline water. (4) Fine-bubble acidic water obtained by mixing oxygen nanobubbles with alkaline water.

Here, the infusion produced by the infusion production device 10 will be described in detail.
In this Embodiment, the fine bubble acidic water produced | generated as an infusion solution is what mixed the nano bubble (henceforth hydrogen nano bubble) and chemical | medical solution by hydrogen gas with acidic water.
The fine-bubble alkaline water is obtained by mixing nanobubbles with hydrogen gas, carbon gas or oxygen gas (hereinafter, nanobubbles with carbon dioxide are referred to as carbon nanobubbles and oxygen nanobubbles with oxygen gas) in alkaline water.

  In the present embodiment, the fine bubble mixed electrolyzed water W (infusion) is made into fine bubble acidic water containing a chemical solution by switching the regulating valves V36 and V37 (see FIG. 3) by the control unit 315. Although the fine bubble acidic water and the fine bubble alkaline water are not mixed in the (merging portion 313 from the acidic water reservoir 310 and the alkaline water reservoir 312), the fine bubble acidic water and the fine bubble alkaline water are not mixed. By separately injecting into blood, it will be in the state mixed in blood.

As shown in FIG. 4, when mixing the hydrogen nanobubbles B _H and the chemical M in acidic water A _C, hydrogen nanobubbles B _H becomes negative potential, chemical M is a positive potential. For this reason, the chemical solution M is drawn around the hydrogen nanobubbles B _H surrounded by the acidic water A _C and gathers so as to surround, thereby forming the hydrogen nanobubbles B _H as a hollow capsule structure.
Furthermore, when mixing the oxygen nanobubbles B _O and nutrients N in alkaline water A _L, oxygen nanobubbles B _O becomes negative potential, nutrients N is a positive potential. Therefore, the nutrients N are drawn around the oxygen nanobubbles B _O surrounded by the alkaline water A _L and gathered so as to surround them, whereby the oxygen nanobubbles B _O are configured as a hollow capsule structure.

When acidic water of fine-bubble acidic water and alkaline water of fine-bubble alkaline water are mixed, they are neutralized, but nanobubbles have a negative potential, so that the nanobubbles repel each other and the nanobubbles do not bond.
Accordingly, and hydrogen nanobubbles B _H by acid water A _C shown in FIG. 4, hydrogen nanobubbles B _H with alkaline water A _L, oxygen nanobubbles B _O by alkaline water A _L, carbonate nanobubbles B _C is by alkaline water A _L, respectively It flows while floating in the blood without binding.
Therefore, nanobubbles surrounded by acidic water maintain acidity, and nanobubbles surrounded by alkaline water also maintain alkalinity. Therefore, nanobubbles by acidic water and alkaline water have an acidic and alkaline effect even in blood. be able to.

Therefore, the hollow capsule by hydrogen nanobubbles B is in a state of maintaining the characteristics of the acidic water can reach the acidic water containing the chemical ill odd cells.
In this way, the infusion solution is delivered to the blood in the blood vessel by drip or a catheter, so that the medicinal solution is transported by the hollow capsule structure of nanobubbles.

As shown in FIG. 5, in the case of systemic chemotherapy by infusion, an infusion solution is supplied to a venous blood vessel and flows through the heart to the artery. Since the infusion flows through blood vessels throughout the body, it reaches not only the primary lesion but also the metastatic lesion.
In addition, as shown in FIG. 6, in the case of local chemotherapy using a catheter, an infusion solution can be supplied intensively toward a diseased cell.

  Since the entrance to the lesion cell facing the blood vessel is larger in the lesion cell than in the normal cell, the particle size (bubble diameter) of the bubble refinement (nanobubble) by the second micronizer 302c shown in FIG. By setting the size so that it cannot enter normal cells but can enter lesion cells, the drug solution M having a hollow capsule structure of hydrogen nanobubbles B (see FIG. 4) can be sent to the primary lesion or metastatic lesion.

The control unit 315 administers the infusion to the patient in the following order.
First, the control unit 315 supplies fine bubble alkaline water obtained by mixing hydrogen gas and carbon dioxide gas into alkaline water as nanobubbles as fine bubble mixed electrolyzed water to a tube connected to the connection unit 314 and administers it to the patient. .

Fine-bubble alkaline water containing hydrogen nanobubbles flows in the blood, so that deposits such as lipid and corsterol attached to the inner wall of the blood vessel can be decomposed and removed from the blood vessel.
Further, alkaline water containing carbonic acid nanobubbles can adsorb and discharge waste products dissolved in blood, and promote blood circulation, so that the blood circulation state can be improved. Furthermore, the carbonic acid nanobubbles of fine bubble alkaline water can activate the digestive function.
Therefore, a blood vessel can be washed by using microbubble alkaline water containing hydrogen nanobubbles and carbonic acid nanobubbles as an infusion solution as microbubble mixed electrolyzed water.

  Next, the control unit 315 supplies fine bubble acidic water obtained by mixing hydrogen gas into acid water as nanobubbles as fine bubble mixed electrolyzed water to a tube connected to the connecting unit 314 and administers it to the patient.

  Microbubble acidic water containing hydrogen nanobubbles is highly permeable and has a negative potential, and therefore is attracted to a lesion having a positive potential, so that the hydrogen nanobubbles can enter the entrance to a lesion cell. Therefore, the hydrogen nanobubbles function as a hollow capsule, filling the entrance and creating a complete embolization state, cutting off nutrition to the tumor and combining it with the active oxygen that caused the tumor with active hydrogen. Reduce. At the same time, the hydrogen nanobubbles collapse over several hours, releasing the drug solution into the tumor. Thus, the hydrogen nanobubble contained in the fine bubble acidic water can be an optimal drug-eluting embolic material.

  Hydrogen nanobubbles disappear in about 4 hours, but carbonic acid nanobubbles float in the blood without disappearing any more. Therefore, after administering fine bubble alkaline water in which carbonated nanobubbles are contained in alkaline water together with hydrogen nanobubbles, when administering fine bubble acidic water containing hydrogen nanobubbles, do not administer alkaline water containing carbonated nanobubbles. However, the effect of alkaline water containing carbonic acid nanobubbles is maintained by the previous administration.

  The bactericidal power of acidic water loses its function instantly if there is protein or blood clot. Therefore, by making the nanobubbles contained in the fine-bubble alkaline water into hydrogen nanobubbles, the sterilizing power of acidic water can be maintained by floating and dissolving the deposits of proteins and clots.

Finally, the control unit 315 sends fine bubble alkaline water obtained by mixing oxygen gas and carbon dioxide gas into alkaline water as nanobubbles as fine bubble mixed electrolyzed water to a tube connected to the connecting unit 314 and administers it to the patient. To do. When mixing oxygen gas with alkaline water, the controller 315 instructs the nutrient input unit 308 to add nutrients to the alkaline water.
Since nutrients for enzymes in blood are added to fine-bubble alkaline water containing oxygen nanobubbles, the enzymes can be activated.

  Thus, the weakened lesion cells can be replaced with healthy cells by the antioxidant action by the activation of the enzyme in the fine bubble alkaline water while healing with the chemical solution contained in the fine bubble acidic water by the hydrogen nanobubbles. By repeating such a process, the natural healing power can be increased and the medical condition can be recovered.

  In the above embodiment, the infusion generation device 10 appropriately generates only fine bubble acidic water or only fine bubble alkaline water as an infusion and administers it to the patient. Can also be mixed under the control of the control unit 315 to generate an infusion.

  The infusion generation device of the present invention is suitable for a hospital where a patient who has difficulty in exercising is hospitalized or a facility where an elderly person moves in.

DESCRIPTION OF SYMBOLS 10 Infusion production | generation apparatus 20 Electrolyzed water production | generation unit 21 Pure water tank 22 Filter 23 Electrolyzed water production | generation part 24 Acidic water tank 25 Alkaline water tank 26 Control part 30 Nanobubble mixing unit 301 1st microbubble mixer 301a 1st gas-liquid mixing Device 301b first pump 301c first micronizer 302 second microbubble mixer 302a second gas-liquid mixer 302b second pump 302c second micronizer 303 acidic water storage tank 304 alkaline water storage tank 305 electrolysis unit 306 Chemical solution input unit 307 Carbon dioxide cartridge 308 Nutrient input unit 309 First sterilization unit 310 Acidic water storage unit 311 Second sterilization unit 312 Alkaline water storage unit 313 Junction unit 314 Connection unit 315 Control unit H1, H2 hose C1, C2 coupler P11 pump P21 pump 31 pump V21 control valve V24 automatic three-way valve V31 automatic three-way valve V32 automatic three-way valve V33 automatic valve V34 automatic valve V35 automatic valves V36, V37, V38 regulating valve M solution A acidic water B hydrogen nanobubbles S film portion W fine bubbles mixed electrolyzed water

Claims (3)

An electrolyzed water generating unit that generates acidic water and alkaline water from raw water;
Fine-bubble acidic water in which hydrogen nanobubbles and chemicals are mixed in acidic water sent from the electrolyzed water generating unit, or fine-bubble alkaline water in which hydrogen nanobubbles are mixed in alkaline water sent from the electrolyzed water generating unit A nanobubble mixing unit that generates one or both as an infusion ,
The nano-bubble mixing unit includes a fine-bubble mixer that mixes nano-bubbles with acid water and alkaline water to form fine-bubble acidic water and fine-bubble alkaline water, and fine-bubble acidic water from the fine-bubble mixer. An infusion production apparatus comprising: a tank for storing fine-bubble alkaline water; and a pipe for circulating fine-bubble acidic water and fine-bubble alkaline water between the fine-bubble mixer and the tank .   The said nano bubble mixing unit is an infusion production | generation apparatus of Claim 1 which produces | generates the infusion by which a carbon dioxide gas was further mixed as a mixed gas in the said alkaline water.   The infusion generation device according to claim 1 or 2, wherein the nanobubble mixing unit generates an infusion in which oxygen gas and nutrients are further mixed as a mixed gas in the alkaline water.

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