JP6043900B1 - Ultra fine bubble aqua jet device with internal combustion engine. - Google Patents

Abstract

An ultra fine bubble aqua jet device using an internal combustion engine capable of producing ultra fine bubbles (nano bubbles) having high functionality in a place where there is no electric power such as the ocean. Resonant foaming apparatus by sucking water from a water source 1 using a primary pump 3 and sending the water to a resonance ejector 15, adjusting pressure reduction and gas flow rate with a needle valve 13, mixing air and water with a resonance ejector 15, 16, microbubbles of primary fine bubbles are generated. The generated primary microbubbles are subjected to vacuum cavitation by the secondary pump 14 to produce ultrafine bubbles of secondary fine bubbles. The internal combustion engine 6, 21 has a high rotational speed, so that it produces ultra-reactive bubble water having a stronger reactivity than that produced by an electric pump. [Selection] Figure 1

Description

  The present invention relates to an ultra fine bubble aqua jet by an engine of an internal combustion engine.

Research on microbubbles and nanobubbles has just begun 20-25 years ago, and the seawater and freshwater habits of Masayoshi Takahashi of AIST introduced at the Nagoya Expo live in the same tank. Interest in micro-bubbles has spread worldwide through demonstration cases that are possible.
At about the same time, the applicant conducted research on microbubbles using hydrogen, and the patent for reducing hydrogen water was first recognized worldwide.
According to the “2012 Microbubbles / Nanobubbles International Standards Promotion Project Results Report”, microbubbles / nanobubbles are tentatively bubbled from 0.8 to 1 mm, and below this, 0.05 It is agreed that ˜0.1 mm or more is referred to as sub-millibubble, sub-milli bubble or less, 20 μm to 1 μm or more as microbubble, and 20 μm to 1 μm or less as ultrafine bubble.
Microbubble production methods include simple methods using an ejector, Venturi tube method, SPG membrane passage method, pressurized and reduced pressure method, ultrasonic vibration method, gas-liquid swirl two-phase method, and cavitation method (including cavitation on the back of the screw) ), Etc., but all of them are cloudy because they contain microbubbles with a large bubble size.
In the research conducted by the present applicant, it has been confirmed that when a magnetic treatment is used in combination with the generation of hydrogen microbubbles, an antioxidant hydrogen radical is generated. Also, according to ultrafine bubbles by cavitation that creates microbubbles by resonant foaming and expands and crushes the bubbles under vacuum conditions, air and oxygen ultrafine bubbles generate measurable radicals, and hydrogen Fine bubbles have been confirmed to produce measurable reduced radicals.
Therefore, the difference between this inventor's previous ultra fine bubble and this application will be compared.

Reference 1 is the “method for producing ultrafine bubbles having an oxidizing radical or a reducing radical by resonance foaming and vacuum cavitation and an ultrafine bubble water producing apparatus” invented by the present applicant.
In this patent, all power sources use motors that require electric power, so they cannot be used at sea or in undeveloped land where there is no electric power. The present application is different because it uses an internal combustion engine that rotates at high speed and can be used everywhere, and provides an ultra-fine bubble manufacturing apparatus that is highly responsive and versatile.

Japanese Patent Application No. 2015-163221

Problems to be solved by the invention

Since the ultra fine bubble by air and oxygen promotes the growth of living organisms, the growth of living organisms is promoted by crop cultivation, cultivating fisheries, poultry farming, pig farming, cattle fattening, etc., and aging progresses within a short time. Since it grows quickly, it has been found that the supply of feed is small and the economic effect is great.
In addition, the ultrafine bubble under oxidizing conditions raises the oxygen concentration in the water system and generates the oxidation radical activity of water, so that the purification of the water system proceeds very quickly by promoting the growth and reproduction of useful organisms.
In particular, the ultra-fine bubble aqua jet device under oxidizing conditions promotes the habitat of various small organisms by simultaneously supplying oxygen and purifying water systems using ultra-fine bubbles without damaging organisms as a driving force for ships. Used as an environmentally friendly ship propulsion device.
Ultrafine bubble hydrogen water has an antioxidant function in vivo and is known to be effective for anti-aging, prevention of lifestyle-related diseases, and prevention of cancer.
Recent research has shown that it is also effective in treating cancer, and water containing hydrogen is sold under the names of hydrogen water, active hydrogen water, micro / nano bubble hydrogen water, and the like.
However, on the domestic ocean, there is no power source in fields without power and in remote forest fields, so it is difficult to produce the ultra fine bubble water in these areas.
The production of ultra fine bubble water by an engine of an internal combustion engine that is not electric is necessary for aquaculture and fisheries on the ocean, to improve productivity of farms with no power source and undeveloped agriculture, to promote livestock in undeveloped land, and to promote undeveloped countries Therefore, the provision of the device is a problem.
In order to solve this problem, the present application has proposed an apparatus for producing ultrafine bubble water using an engine of an internal combustion engine that can eject and distribute a large amount of ultrafine bubbles anywhere.

Means for solving the problem

All of the nanobubble generators currently in widespread use are a system in which water is circulated in a water tank and a processing apparatus to store fine bubbles, and the output is small, and the processing capacity is 300 liters per minute or less.
As described above, there is no technology for sucking up a large amount of water and directly ejecting ultrafine bubbles, and a device that can operate on the sea, in a farm field without a power source, or in an undeveloped land is necessary.
Therefore, an apparatus using an internal combustion engine that rotates at high speed is provided.
(1) An apparatus for producing ultra fine bubble water of air capable of generating oxidizing radicals connected to two internal combustion engine engine pumps.
(2) An apparatus for producing ultrafine bubble water of empty oxygen or ozone gas capable of generating oxidizing radicals connected to two internal combustion engine engine pumps.
(3) A device for producing ultra-fine bubble water of hydrogen that is connected to two internal combustion engine engine pumps and generates reduced hydrogen water.
(4) Production of air, oxygen, or hydrogen ultra fine bubble water that can generate and generate oxidized radicals or reduced radicals with a structure connected to two pumps arranged on the same power shaft of the engine apparatus.
(5) Air, oxygen, ozone gas, or hydrogen that is capable of generating radicals stronger than an electric pump with a structure connected to two pumps connected by the same power shaft of the engine and a differential gear. A gas ultrafine bubble water production device was proposed.
<Generates oxidation radicals connected to two internal combustion engine engine pumps
Air Ultra Fine Bubble Aqua Jet Device>

It is known that an ultrafine bubble of air having a size of 1 μm or less activates various enzyme reactions in a living body to accelerate the growth of the living body or grow the living body greatly.
This speeds crop growth and increases yield. In pig farming, poultry farming, and fish farming, which require rapid growth, it has been proved that the economic effect is enhanced because they mature with less feed.
Therefore, an ultrafine bubble water production apparatus connected to an internal combustion engine pump that enables production of ultrafine bubble water in any place where there is no power is provided.
<Structure of Air Ultra Fine Bubble Aqua Jet 2 Engine Pump Device>

As shown in FIG. 1, the power plant includes a primary engine 6 having a fuel tank 7 for moving the primary pump 3, a group of clutches 5 connected thereto, and a secondary pump 21 having a fuel tank 22 for moving the secondary pump 18. And two groups of clutches 20 connected thereto.
The ultra fine bubble production system is a system that supplies power from the engine motor 6 of the internal combustion engine, sucks water from the water source 1 and the water absorption pipe 2 using the primary pump 3, and sends the water to the resonance ejector 15 through the water supply pipe 10. A system for generating gas-liquid mixed microbubbles from air suction includes an intake port 11, a needle valve 13, a resonance adjustment vacuum gauge 14, a constant pressure gas flow flow meter 12, a resonance ejector 15, and a resonance foaming device 16, and decompression and gas flow rate. The needle valve 13 is adjusted, air and water are mixed by the resonance ejector 15, and microbubbles of primary fine bubbles are generated by the resonance foaming device 16.
The generated primary microbubbles are subjected to vacuum cavitation by the secondary pump 14 to produce secondary fine bubbles of ultrafine bubbles. Since the engine of an internal combustion engine has a high rotational speed, it produces ultra-fine bubble water with stronger reactivity than that produced by an electric pump.
<Operation of Air Ultra Fine Bubble Aqua Jet 2 Engine Pump Device>

(1) In the process up to the production of microbubbles, the water suction pump 3 and the internal combustion engine 6 provided with the fuel tank 7 are connected via the clutch 5. The engine is operated and the number of revolutions is adjusted by the accelerator lever 9, and transmission of power is connected to the pump 3 by operating the clutch lever 8.
(2) Water is sucked from the water source 1 through the water absorption pipe 2 and the primary pump 3 performs water absorption operation.
(3) The water absorbed by the primary pump 3 is sent to the resonance ejector 15.
(4) Air is drawn from the intake port 11, passes through the low-pressure flow gas flow meter 12, and is sent to the resonance ejector 15.
(5) Water is jetted in the resonance ejector 15, air is mixed in by the jet water flow, the suction side is depressurized, and the sound adjustment vacuum gauge 14 is activated.
(6) In the resonance ejector 15, the air taken in from the intake port 11 is adjusted by the resonance adjustment needle valve 13 while confirming the flow rate and pressure reduction by the low pressure flow gas flow meter 12 and the sound adjustment vacuum gauge 14, and the resonance foaming device 16 is set to a resonance decompression suitable for generating resonance of primary fine bubbles.
(7) Water containing fine air bubbles generated in resonance in the resonance foaming device 16 is sent to the secondary pump 18 through the water guide pipe 17.
(8) In the process up to the production of ultra fine bubbles of air, the water absorption pump 3 and the secondary internal combustion engine 21 provided with the fuel tank 22 are connected via the clutch 5. The secondary engine and the secondary pump are actuated to adjust the rotational speed with the accelerator lever 9, and the transmission of power is connected to the pump 18 by operating the clutch lever 8.
(9) The operation is performed by operating the accelerator lever 9 and the clutch lever 8 to move the primary pump 3 and the secondary pump 21, and confirming the flow rate and pressure reduction with the low-pressure flow gas flow meter 12 and the sound adjustment vacuum gauge 14, and resonance. Adjust with the adjustment needle valve 13 and set the resonance pressure to be suitable for the generation of resonance of the primary fine bubbles in the resonance foaming device 16 to store the ultrafine bubbles of colorless and transparent air in the storage tank 36 or to eject them. Ejected as aqua jet from the device.
<Enhanced generation of oxidation radicals connected to two internal combustion engine engine pumps
Oxygen or ozone ultra-fine bubble aqua jet device>

Oxygen or ozone ultrafine bubbles with a size of 1 μm or less are used for disinfection of drug-resistant bacteria that are resistant to many fungicides, such as activating the oxidizing radical strength that causes an oxidative reaction and exerting strong bactericidal power. It is known to have a bactericidal effect over ozone treatment.
Therefore, an oxygen or ozone ultrafine bubble water production apparatus using an engine pump is necessary to improve medical functions in regions where there is no electricity overseas.
<Oxygen or ozone ultra fine bubble aqua jet 2 engine pump device structure>

As shown in FIG. 2, the power plant includes a primary engine 6 having a fuel tank 7 for moving the primary pump 3, a group of clutches 5 connected thereto, and a secondary pump 21 having a fuel tank 22 for moving the secondary pump 18. And two groups of clutches 20 connected thereto, and an oxygen supply device or a gas supply device related to ozone production.
The ultra fine bubble manufacturing system supplies power from the engine motor 6 of the internal combustion engine, sucks water from the water source 1 and the water absorption pipe 2 using the primary pump 3, and sends the water to the resonance ejector 15. In the case of oxygen, it is connected from the oxygen gas cylinder 26 through the gas pressure reducing flow rate adjusting device and the gas cleaning device 33 to the main body device for producing the ultra fine bubble, oxygen and water are mixed by the resonance ejector 15, and primary by the resonance foaming device 16 Generates microbubbles. The generated primary microbubbles are subjected to vacuum cavitation by the secondary pump 14 to generate secondary ultra-bubble oxygen ultrafine bubble water. Ozone is connected to the main unit from the oxygen gas cylinder 26 through the gas decompression flow rate control devices 27 to 32, the gas cleaning device 33, and the ozone production device 35, and ozone and water are mixed by the resonance ejector 15 and primary by the resonance foaming device 16. Generates microbubbles.
The generated primary oxygen or ozone microbubbles are subjected to vacuum cavitation by the secondary pump 14 to generate secondary fine bubble oxygen or ozone ultrafine bubble water.
The generated ultra fine bubbles are stored in the storage tank 36 or ejected from the ejection device 25 as an aqua jet.
<Operation of oxygen or ozone ultra fine bubble aqua jet 2 engine pump device>

(1) In the process up to the production of microbubbles, the water suction pump 3 and the internal combustion engine 6 provided with the fuel tank 7 are connected via the clutch 5. The engine is operated and the number of revolutions is adjusted by the accelerator lever 9, and transmission of power is connected to the pump 3 by operating the clutch lever 8.
(2) Water is sucked from the water source 1 through the water absorption pipe 2 and the primary pump 3 performs water absorption operation.
(3) The water absorbed by the primary pump 3 is sent to the resonance ejector 10.
(4) The oxygen is adjusted to a predetermined pressure while opening the main stopper 27 of the oxygen cylinder 26, confirming the gas amount with the gas pressure meter 28, and confirming the decompression gas meter 30 with the decompression valve 29.
(5) The gas flow rate is adjusted by the resonance adjusting gas needle valve 32 while viewing the gas flow meter 31 after adjusting the gas pressure.
(6) The oxygen gas whose flow rate has been adjusted is passed through the deodorizing filtration device 33 filled with activated carbon, passed through the low-pressure flow gas flow meter 12, and sent to the resonance ejector 15.
(7) In the case of ozone gas, the main plug 27 of the oxygen cylinder 26 is opened, the gas amount is confirmed with the gas pressure meter 28, and the pressure is adjusted to a predetermined pressure while checking the pressure reduced gas meter 30 with the pressure reducing valve 29. The gas flow rate is adjusted by the resonance adjusting gas needle valve 32 while looking at the gas flow meter 31.
(8) The oxygen gas whose flow rate is adjusted passes through the deodorizing filter device 33 filled with activated carbon, passes through the ozone production device 35, passes through the low pressure flow gas flow meter 12, and is sent to the resonance ejector 15.
(9) Water is jetted in the resonance ejector 15, oxygen or ozone is mixed in the jet water flow, the intake side is depressurized, and the sound adjustment vacuum gauge 14 is operated.
(10) In the resonance ejector 15, oxygen or ozone gas is adjusted by the resonance adjustment needle valve 13 while confirming the flow rate and pressure reduction by the low-pressure flow gas flow meter 12 and the sound adjustment vacuum gauge 14, and 1 in the resonance foaming device 16. The resonance pressure is set to be suitable for the generation of resonance of the next microbubble.
(11) Water containing oxygen or ozone fine bubbles generated in resonance in the resonance foaming device 16 is sent to the secondary pump 18 through the water guide pipe 17.
(12) In the process up to the production of ultrafine bubbles of oxygen or ozone, the water absorption pump 3 and the secondary internal combustion engine 21 provided with the fuel tank 22 are connected via the clutch 5.
(13) For production of oxygen or ozone ultra fine bubbles, the secondary engine and the secondary pump are operated to adjust the rotational speed with the accelerator lever 9, and the power is transmitted to the secondary pump 18 by operating the clutch lever 8. Connect with.
(14) For the operation, the accelerator lever 9 and the clutch lever 8 are operated to move the primary pump 3 and the secondary pump 18, and the flow rate and pressure reduction are confirmed by the low pressure flow gas flow meter 12 and the ring adjustment vacuum gauge 14, and the resonance. Adjusting with the adjusting needle valve 13, the resonant depressurization suitable for the resonant foaming of the primary fine bubbles is set in the resonant foaming device 16 to generate oxygen or ozone microbubbles, and this is vacuum cavitation with the secondary pump 18. To produce a colorless transparent oxygen or ozone ultra fine bubble and store it in the storage tank 36 or eject it from the ejection device 25 as an aqua jet.
<Generates reducing radicals connected to two internal combustion engine engine pumps
Hydrogen ultrafine bubble water production equipment>

Hydrogen ultrafine bubbles with a size of 1 μm or less have an active oxygen scavenging function that is toxic in vivo, such as having an antioxidant function to generate a reducing radical that causes a reduction reaction and scavenging active oxygen in the living body. It has been known.
Therefore, in order to improve medical functions in regions where there is no electricity overseas, it is necessary to localize medical activities by providing a hydrogen ultrafine bubble water production device using an engine pump.
<Structure of Hydrogen Ultra Fine Bubble Aqua Jet 2 Engine Pump Device>

As shown in FIG. 3, the power plant has a primary engine 6 having a fuel tank 7 for moving the primary pump 3, a group of clutches 5 connected thereto, and a secondary engine 21 having a fuel tank 22 for moving the secondary pump 18. And two groups of clutches 20 connected thereto, and a hydrogen supply device.
The water supply system for producing ultra fine bubble water supplies power from the engine motor 6 of the internal combustion engine, sucks water from the water source 1 and the water suction pipe 2 using the primary pump 3, and sends the water to the resonance ejector 15. In the resonance ejector, water and hydrogen gas are mixed and sent to a resonance foaming device to generate microbubbles of primary fine bubbles. The generated micro bubbles are sent to the secondary pump 18 to generate ultra final bubbles by vacuum cavitation.
Further, this process will be described in detail. Hydrogen is connected from the hydrogen gas cylinder 38 through the gas decompression flow rate adjusting device and the gas cleaning device 33 to the main body device for producing ultrafine bubble water, and the resonance foaming device 16 generates primary fine bubbles. Generates microbubbles.
Hydrogen is connected from the hydrogen gas cylinder 38 through the gas decompression flow rate control devices 29 to 32 and the gas cleaning device 33 to the main body of the ultra fine bubble manufacturing, and the resonance ejector 15 mixes hydrogen and water. Microbubbles of fine bubbles of hydrogen are generated.
The generated primary hydrogen microbubbles are subjected to vacuum cavitation by the secondary pump 18 to generate secondary ultrabubble hydrogen ultrafine bubble water.
<Operation of Hydrogen Ultra Fine Bubble Aqua Jet 2 Engine Pump Device>

(1) In the process up to the production of microbubbles, the water suction pump 3 and the internal combustion engine 6 provided with the fuel tank 7 are connected via the clutch 5. The engine is operated and the number of revolutions is adjusted by the accelerator lever 9, and transmission of power is connected to the pump 3 by operating the clutch lever 8.
(2) Water is sucked from the water source 1 through the water absorption pipe 2 and the primary pump 3 performs water absorption operation.
(3) The water absorbed by the primary pump 3 is sent to the resonance ejector 10.
(4) The hydrogen is adjusted to a predetermined pressure while opening the main stopper 27 of the hydrogen cylinder 38, confirming the gas amount with the gas pressure meter 28, and confirming the decompression gas meter 30 with the decompression valve 29.
(5) The gas flow rate is adjusted by the resonance adjusting gas needle valve 32 while viewing the gas flow meter 31 after adjusting the gas pressure.
(6) The oxygen gas whose flow rate has been adjusted is passed through the deodorizing filtration device 33 filled with activated carbon, passed through the low-pressure flow gas flow meter 12, and sent to the resonance ejector 15.
(7) Water is jetted in the resonance ejector 15, hydrogen is mixed in the jet water flow, the intake side is depressurized, and the adjustment vacuum gauge 14 showing depressurization suitable for resonance operates.
(8) In the resonance ejector 15, the hydrogen gas is adjusted by the resonance adjustment needle valve 13 while confirming the flow rate and pressure reduction by the low-pressure flow gas flow meter 12 and the sound adjustment vacuum gauge 14, and is first-order in the resonance foaming device 16. The resonance pressure is set to be suitable for the generation of resonance of fine bubbles.
(9) Water containing fine hydrogen bubbles resonated in the resonance foaming device 16 is sent to the secondary pump 18 through the water guide pipe 17.
(10) In the process up to the production of ultra fine bubbles of hydrogen, the secondary internal combustion engine 21 provided with the fuel tank 22 and the secondary pump 18 are connected via the clutch 5.
In the secondary pump 18, microbubbles of primary fine bubbles are crushed by vacuum cavitation to generate hydrogen ultrafine bubbles.
(11) In the operation of production of ultra fine bubbles of hydrogen, the secondary engine and the secondary pump are operated to adjust the rotation speed with the accelerator lever 9, and the power is transmitted to the secondary pump 18 by operating the clutch lever 8. Connect with.
(12) For the operation, the accelerator lever 9 and the clutch lever 8 are operated to move the primary pump 3 and the secondary pump 21, and the flow rate and pressure reduction are confirmed by the low pressure flow gas flow meter 12 and the sound adjustment vacuum gauge 14, and the resonance. Adjusting with the adjusting needle valve 13, the resonant depressurization suitable for the resonant foaming of the primary fine bubbles is set in the resonant foaming device 16 to generate oxygen or ozone microbubbles, and this is vacuum cavitation with the secondary pump 18. To produce a colorless and transparent ultrafine bubble of hydrogen and store it in the storage tank 36.
<Air or oxygen, ozone, hydrogen, nitrogen, or carbon dioxide ultrafine bubble water production device that connects two pumps in parallel on the same power shaft of the engine>

FIG. 4 shows an apparatus for producing ultra-fine bubble water connected in parallel, in which two pumps are operated by a single engine.
As the gas to be used, any one of air, oxygen, ozone, hydrogen, nitrogen, and carbon dioxide gas is supplied from each gas cylinder 40 according to the application.
The production process of ultra fine bubble water is almost the same as the above method, and one engine is used. Power transmission is a system in which two pumps are connected directly to the same propeller shaft from the engine via a clutch, and the two pumps are operated by one engine.
The merit is that the size of the apparatus becomes compact and can be miniaturized.
<Structure of Ultra Fine Bubble Aqua Jet Single Engine Parallel Arrangement Pump Device>

As shown in FIG. 4, the power plant is parallel to the primary engine 6 having a fuel tank 7 for moving the primary pump 3 and the same propeller shaft 4-1 as the primary pump 3 connected to the clutch 5 connected thereto. The secondary pump 18 and the gas supply devices 40 to 34 are connected directly.
The water supply system for producing ultra fine bubble water supplies power from the engine motor 6 of the internal combustion engine, sucks water from the water source 1 and the water suction pipe 2 using the primary pump 3, and sends the water to the resonance ejector 15. In the resonance ejector, water and gas are mixed and sent to a resonance foaming device to generate microbubbles of primary fine bubbles. The generated microbubbles are sent to the secondary pump 18 connected to the same propeller shaft 4-1 as the primary pump 3 connected to the primary engine 6 and the clutch 5 connected thereto, and used as an ultra fine bubble of gas used by vacuum cavitation. Is generated.
Use gas to promote the growth of plants and animals, oxygen gas for lifesaving of critically ill patients, ozone gas for drug-resistant pathogen sterilization cleaning, and removal of active oxygen in the body to maintain health. The gas cylinder can be selected depending on the application, such as hydrogen gas for the purpose, nitrogen gas for maintaining the freshness of fresh fish, tuna, etc., and carbon dioxide for hypnotic transport of the living body.
<Operation of Ultra Fine Bubble Aqua Jet Single Engine Parallel Arranged Pump Device>

(1) The gas to be used is any one of air, oxygen, ozone, hydrogen, nitrogen and carbon dioxide, and each gas cylinder 40 is installed according to the application.
(2) In the process up to the production of microbubbles, the water suction pump 3 and the internal combustion engine 6 provided with the fuel tank 7 are connected via the clutch 5. The engine is operated and the number of revolutions is adjusted by the accelerator lever 9, and transmission of power is connected to the pump 3 by operating the clutch lever 8.
(3) The water is sucked in from the water source 1 through the water absorption pipe 2 and the primary pump 3 performs the water absorption operation.
(4) The water absorbed by the primary pump 3 is sent to the resonance ejector 10.
(5) The main stopper 27 of the gas cylinder 26 is opened, the amount of gas is confirmed with the gas pressure meter 28, and the pressure is adjusted to a predetermined pressure while the decompression valve 29 is confirmed with the decompression gas meter 30.
(6) The gas flow rate is adjusted by the resonance adjusting gas needle valve 32 while looking at the gas flow meter 31 after adjusting the gas pressure.
(7) The gas whose flow rate is adjusted passes through the deodorizing filter device 27 filled with activated carbon, passes through the low-pressure flow gas flow meter 12, and is sent to the resonance ejector 15.
(8) Water is jetted in the resonance ejector 15, gas is mixed in the jet water flow, the suction side is depressurized, and the sound adjustment vacuum gauge 14 is operated.
(9) In the resonance ejector 15, the gas is adjusted by the resonance adjustment needle valve 13 while confirming the flow rate and pressure reduction by the low-pressure flow gas flow meter 12 and the resonance adjustment vacuum gauge 14, and is first-order fine in the resonance foaming device 16. Resonance decompression suitable for bubble resonance is set.
(10) The fine bubble microbubble water of the gas generated in resonance in the resonance foaming device 16 is sent to the secondary pump 18 connected to the same propeller shaft 4-1 as the primary pump 3 through the water guide pipe 17. In the secondary pump, ultra fine bubbles of gas used are generated by vacuum cavitation.
<Production device for air, oxygen, ozone, hydrogen, nitrogen, or carbon dioxide ultra fine bubble water with two pumps arranged in series on the same power shaft of the engine>

FIG. 5 shows a series-connected ultrafine bubble water production apparatus in which two pumps are operated by a single engine.
As in the parallel type, the gas to be used is supplied from each gas cylinder 40 in accordance with the use of any of air, oxygen, ozone, hydrogen, nitrogen, and carbon dioxide.
The production process of ultra fine bubble water is almost the same as the above method, and one engine is used.
<Structure of Ultra Fine Bubble Aqua Jet Single Engine Series Arrangement Pump Device>

As shown in FIG. 5, the power unit is connected to the primary pump 3 via a primary engine 6 having a fuel tank 7 for moving the primary pump 3 and a differential gear 4-2 connected to a clutch 5 connected thereto. , A device connected to a secondary pump arranged in series on the same propeller shaft 4-1 via a differential gear -4-3, and a hydrogen supply device.
The water supply system for producing ultra fine bubble water supplies power from the engine motor 6 of the internal combustion engine via the differential gear 4-2 and sucks up water from the water source 1 and the water intake pipe 2 using the primary pump 3. To the resonance ejector 15.
In the resonance ejector, water and gas are mixed and sent to a resonance foaming device to generate microbubbles of primary fine bubbles.
The generated microbubbles send power to the secondary pump 18 via the primary engine 6, the clutch 5 connected to the primary engine 6, and the differential gear 4-3, and generate ultrafine bubbles of gas to be used by vacuum cavitation. .
As in the case of parallel pump installation, air is used to promote the growth of plants and animals, oxygen gas is used to save critically ill patients, ozone gas is used for drug-resistant pathogen sterilization cleaning, and biological activity Select gas cylinders depending on the application, such as using hydrogen gas for maintaining health by removing oxygen, nitrogen gas for maintaining freshness of fresh fish, tuna, etc., and carbon dioxide for hypnotic transport of living organisms. It is possible.
<Operation of Ultra Fine Bubble Aqua Jet Single Engine Series Arranged Pump Device>

(1) The gas to be used is any one of air, oxygen, ozone, hydrogen, nitrogen and carbon dioxide, and each gas cylinder 40 is installed according to the application.
(2) In the process up to the production of microbubbles, the water suction pump 3 and the internal combustion engine 6 provided with the fuel tank 7 are connected via the clutch 5. The engine is operated and the rotation speed is adjusted by the accelerator lever 9, and the transmission of power is operated by operating the clutch lever 8 and connecting it to the pump 3 via the differential gear 4-2.
(3) The water is sucked in from the water source 1 through the water absorption pipe 2 and the primary pump 3 performs the water absorption operation.
(4) The water absorbed by the primary pump 3 is sent to the resonance ejector 10.
(5) The main stopper 27 of the gas cylinder 40 is opened, the amount of gas is confirmed with the gas pressure meter 28, and the pressure is adjusted to a predetermined pressure while confirming the decompression gas meter 30 with the decompression valve 29.
(6) The gas flow rate is adjusted by the resonance adjusting gas needle valve 32 while looking at the gas flow meter 31 after adjusting the gas pressure.
(7) The gas whose flow rate is adjusted passes through the deodorizing filter device 27 filled with activated carbon, passes through the low-pressure flow gas flow meter 12, and is sent to the resonance ejector 15.
(8) Water is jetted in the resonance ejector 15, gas is mixed in the jet water flow, the suction side is depressurized, and the sound adjustment vacuum gauge 14 is operated.
(9) In the resonance ejector 15, the gas is adjusted by the resonance adjustment needle valve 13 while confirming the flow rate and pressure reduction by the low-pressure flow gas flow meter 12 and the resonance adjustment vacuum gauge 14, and is first-order fine in the resonance foaming device 16. Resonance decompression suitable for bubble resonance is set.
(10) The fine bubble microbubble water of the gas generated in resonance in the resonance foaming device 16 is connected to the same propeller shaft 4-1 as the primary pump 3 through the water guide pipe 17 through the differential gear-4-3. Send to 18. In the secondary pump, ultra fine bubbles of gas used are generated by vacuum cavitation.
Example

Example 1 Effect of the effect of pulverization of air by cavitation and the treatment of fine bubbles by an internal combustion engine on the gas dissolution rate in the solution and the cloudiness of the solution The shear foaming technology has been developed with the emphasis on what kind of method is effective for shearing, by repeating the process based on the generation of fine bubbles by shearing bubbles by mixing them.
In the present invention, microbubbles are generated by gas-liquid mixing and resonance foaming by water injection of an internal combustion engine, and once the foamed microbubbles are expanded by vacuum and crushed by vacuum cavitation, the bubbles are ultrafine. Demonstrate that it becomes an ultra fine bubble.
1) Test apparatus A comparative test was performed on the apparatus of the present inventor's patent No. 3843361 and the apparatus of the present invention, and the state of dissolved gas in water was compared.
(1) Shearing and crushing treatment by ejector and cavitation (Patent No. 3843361) Water is sucked up by a pump, water and air are mixed by an ejector to generate fine bubbles, and then cavitation is performed by a stirrer that rotates at high speed in the tank. To generate microbubbles.
(2) Decompression resonance foaming by an internal combustion engine and double crushing treatment by vacuum cavitation A method of generating ultrafine bubbles in the apparatus of the present invention.
2) Test method Control 1 is a method of shear crushing (Patent No. 3843361). After pumping water with an electric motor, gas-liquid mixing with an ejector, and then using a plurality of stirrers that rotate at high speed under pressure. This is a method of chopping and crushing bubbles. (Microbubble generation)
Control 2 is a method of generating fine bubbles by gas-liquid double crushing processing (Japanese Patent Application No. 2015-163221) using an ultrafine bubble device by resonance foaming using an electric motor and vacuum cavitation.
The resonant foaming and vacuum cavitation according to the present invention enable the gas-liquid double crushing process as in Japanese Patent Application No. 2015-163221 to be performed anywhere using an engine pump of an internal combustion engine that rotates at high speed.
For the measurement, the amount of water used, the amount of air injected, and the amount of undissolved residual air were measured using a meter, the amount of dissolved air, the rate of dissolved air, and the total gas solubility were calculated, and the solution states were compared.
3) Test results Table 1 shows the measurement results.
4) Summary of results The power source of the shearing crushing process of Control 1 is an electric motor, the motor rotation speed is 1,500 to 2,000 rpm, and the power source of the resonance foaming and vacuum cavitation method of Control 2 is also an electric motor. Yes, the rotational speed is 1,500 to 2,000 rpm. In the gas-liquid double crushing process using the engine of the present invention, the rotational speed is 3,000 rpm.
The amount of water injected was set to be approximately the same. The crushing function of the gas-liquid mixed liquid was higher in the gas-liquid double crushing process using the engine of the present invention than in Control 1 and Control 2, and the amount of dissolved gas was also increased.
When the white turbidity of the water was observed, the shear crushing treatment of the control 1 became cloudy, but the resonance foaming and vacuum cavitation method of the control 2 became colorless and transparent. The gas-liquid double crushing treatment using the engine of the present invention did not become cloudy although there was more gas dissolution than control 2.
It is known that in the state of fine bubbles in water, water becomes cloudy when the size of the bubble particles is 10 to 100 nm, but becomes colorless and transparent when the size is 1 nm or less.
Therefore, from the results of this experiment, the gas-liquid double crushing solution using the engine of the present invention in which more gas than the control was dissolved as fine bubbles was colorless and transparent. It is judged that it was proved to be ultrafine bubbles.

Example 2 Oxidative Radical Activity of Gas-Liquid Double Crush Processed Water by Engine Pump It has been considered that a quantitative measurement method for oxidizing radicals is difficult by a chemical method.
However, it was thought that the existence by electron spin resonance method could be measured by chemical method, so that sulfuric acid acidic condition was set, and oxidizing radical of ultra fine bubble water was diluted with sodium thiosulfate diluted normal solution. And the method of titrating the remaining sodium thiosulfate with potassium permanganate was studied.
1) Test method Oxidative radical generation of ultra fine bubble water is generated and disappears instantaneously, so the reaction is carried out using a sodium thiosulfate diluted normal solution (1M / 10000Na ₂ S ₂ O ₃ ) for 10 minutes. It reacts with fine bubble water, and the accumulated amount of oxidized radicals generated (integrated radical) is titrated with a normal solution of potassium permanganate.
The following formula is mentioned as the reaction.
Specifically, 20 ml of ultra fine bubbles was allowed to react with 10 ml of dilute sodium thiosulfate normal solution for 10 minutes, and the remaining M / 10000Na ₂ S ₂ O ₃ was titrated with M / 1000KMnO ₄ under sulfuric acid acidity. The amount of accumulated oxidized radicals was measured.
2) Test results The test results are shown in Table 2.
3) Summary of results As seen in Table 5, the oxidizing radical of the sample nanobubble water is equivalent to one molecule of sodium thiosulfate, and the relationship between sodium thiosulfate molecules and potassium permanganate molecules is also equivalent, calculation of the intensity of KMnO ₄ consumption, M / 1000KMnO ₄ 1ml corresponds to the consumption of KMnO ₄ in 1 [mu] M.
As seen in Table 5, the consumption amount of the oxidizing radical Na ₂ S ₂ O ₃ of the test ultra fine bubble water was measured in terms of M / 1000KMnO ₄ to be titrated.
Na ₂ S ₂ O ₃ by the calculation of the intensity of KMnO ₄ consumption M / 1000KMnO ₄ 1ml corresponds to the consumption of KMnO ₄ in 1 [mu] M, _Na 2 radicals and 2 molecules generated water molecules 2 molecules _{S 2} Since O ₃ reacts to produce one molecule of Na ₂ SO ₄ , water molecules and sodium thiosulfate molecules are in an equivalent relationship.
Calculation formula = 1 μM × titration difference ÷ sampled amount × 1000 = 1 μM × 0.59 ÷ 20 × 1000 ÷ 10 minutes≈3 μM / L / min
That is, the amount of radicals generated by ultrafine bubbles based on ₄ titrations of M / 1000KMnO was calculated as the amount of oxidizing radicals generated in about 3 μM of water per minute per liter of water over time.
This value was higher than the radical generation amount (about 2 μM) of ultra fine bubbles generated by a pump operating with an electric motor (1,500 to 2,000 rpm).

Industrial applicability

It is known that nanobubble water in air increases the dissolved oxygen concentration of water and promotes the activities of aquatic organisms, so that purification of water proceeds. The nanobubble water production apparatus using vacuum cavitation according to the present invention can also perform water treatment at 10 tons per minute. The supply of nanobubble water in the air activates living tissue and accelerates the growth of living organisms, and in crops, strengthens resistance to global warming, so the depletion of marine resources, the crisis of agriculture and forestry industry that will occur in the future Can be overcome by nanobubbles.
Nanobubble hydrogen water has an antioxidant function and is useful for prevention of so-called lifestyle-related diseases such as hypertension, hyperlipidemia, diabetes, heart disease, cerebral infarction, etc., in an aging society, and for cancer. Is possible.
Nano-bubble oxygen water enables the production of high-concentration oxygen water, and therefore has the potential as a new technology that can deal with medical emergency situations. Nanobubble ozone water has a wide range of applications such as hospital facilities and instrument sterilization where drug-resistant bacteria rapidly increase because of its bactericidal power and safety.

Air ultra fine bubble aqua jet 2 engine pump device. Oxygen or ozone ultra fine bubble aqua jet 2 engine pump device. Hydrogen ultra fine bubble aqua jet 2 engine pump device. Ultra fine bubble aqua jet single engine parallel arrangement pump device. Ultra fine bubble aqua jet single engine in-line arrangement pump device.

1 Water source 2 Water absorption pipe 3 Primary pump 4-1 Primary engine propeller shaft 4-2 Primary pump differential gear
4-3 Differential gear for secondary pump
5 Primary engine clutch 6 Primary engine 7 Primary engine fuel tank 8 Clutch lever 9 Engine rotation adjustment lever 10 Water supply pipe 11 from the primary pump 11 Air inlet 12 Low pressure flow gas flow meter 13 Resonance adjustment needle valve 14 Resonance adjustment vacuum gauge 15 Resonant Ejector 16 Resonant Foaming Device 17 Water Pipe from Resonant Foaming Device (Micro Bubble Water Feeding)
18 Secondary pump (vacuum cavitation)
19 Secondary engine propeller shaft 20 Secondary engine clutch 21 Secondary engine 22 Secondary engine fuel tank 23 Water supply pipe from the secondary pump (ultra fine bubble water supply)
24 Pressurizer (Ultra Fine Bubble Compression)
25 Ultra Fine Bubble Blowout Device 26 Oxygen Gas Cylinder 27 Cylinder Main Valve 28 Gas Pressure Meter 29 Pressure Reduction Valve 30 Pressure Reduction Gas Meter 31 Gas Flow Meter 32 Gas Needle Valve 33 Gas Deodorizing Filtration Device 34 Clean Gas Conducting Pipe 35 Ozone Generator 36 Air Ultra Fine Bubble water storage tank 37 Ultra fine bubble oxygen water or ozone water storage tank 38 Hydrogen cylinder 39 Ultra fine bubble hydrogen water storage tank 40 Oxygen gas cylinder, hydrogen gas cylinder, nitrogen gas cylinder or carbon dioxide gas cylinder 41 Oxygen or ozone or hydrogen or , Nitrogen or carbon dioxide ultra fine bubble water storage tank 42 device support base 43 moving caster

Claims (4)

Equipped with two sets of internal and internal combustion engine pump devices, each of which is connected to an internal combustion engine and a water flow pump via a clutch,
A primary pump that takes water from a water source;
A device for supplying air, oxygen gas or ozone gas;
Resonant ejector that takes in air, oxygen gas or ozone gas and mixes with water;
A resonant foaming device that turns microbubbles into a gas mixed with water;
A secondary internal combustion engine pump that creates a vacuum in the entire water system after resonant foaming, and arranged in the order described,
The primary internal combustion engine pump takes water from the water source, pressurizes the water, sends it to the resonance ejector,
Air, oxygen gas or ozone gas is sent from the gas supply device to the resonance ejector.
The resonance ejector is equipped with a decompression meter, a gas flow meter, a resonance adjustment needle valve, and a resonance foaming device.
Mix the water and air sent from the primary internal combustion engine pump or the gas sent from the oxygen gas or ozone gas supply device with a resonance ejector,
At that time, adjust the water and gas supply ratio and pressure reduction with the resonance adjustment needle valve and pressure gauge,
A mixture of water and gas is resonantly foamed with a resonant foaming device and instantly becomes cloudy as microbubbles of primary fine bubbles.
The microbubbles of primary fine bubbles foamed by the resonant ejector and the resonant foaming device are sent to the secondary pump,
Since towards the suction capacity of the water of the secondary internal combustion engine pump is several times greater than the amount of water sent from the primary internal combustion engine engine pump and resonance foaming device under the influence of an ejector vacuum occurs throughout water,
The primary fine bubbles sent from the resonant foaming device are expanded tens of times under vacuum conditions,
Shearing the expanded primary fine bubbles by high-speed rotation of the impeller of the secondary internal combustion engine pump;
With the impact of hitting the casing with water, it is instantly converted from a vacuum condition to a pressurized condition and crushed.
Nano-sized secondary microbubbles are generated by vacuum cavitation that breaks by double cavitation action,
The resulting ultrafine bubbles are ultrafine nano-sized ultrafine bubbles, and the water does not become cloudy.
With the engine of the internal combustion engine, generation of primary fine bubbles by efficient resonance foaming,
Water has an oxidizing radical function by the two-stage refinement process of generating secondary microbubbles generated by vacuum cavitation of a secondary internal combustion engine pump, and it is efficient and fine by controlling the engine output An aqua jet device for jetting out highly reactive air, oxygen or ozone radical radical ultra fine bubble water , characterized by controlling bubble size production and bubble generation. Equipped with two water pumps directly connected to the same power shaft, a primary pump and a secondary pump connected to the same power shaft of the engine of one internal combustion engine via a clutch,
A primary pump that takes water from a water source;
A device for supplying air, oxygen gas or ozone gas ;
A resonant ejector that mixes water and gas,
Resonant foaming device that makes mixed air, oxygen gas, or ozone gas into microbubbles,
A secondary pump that creates a vacuum is arranged in the order described and connected with a water pipe.
The primary pump takes water from the water source, pressurizes the water, sends it to the resonance ejector,
Air, oxygen gas or ozone gas is sent from the gas supply device to the resonance ejector.
The resonance ejector is equipped with a decompression meter, a gas flow meter, a resonance adjustment needle valve, and a resonance foaming device.
Mix the water and air sent from the primary pump or the gas sent from the oxygen gas or ozone gas supply device with a resonance ejector,
At that time, adjust the water and gas supply ratio and pressure reduction with the resonance adjustment needle valve and pressure gauge,
A mixture of water and gas is resonantly foamed with a resonant foaming device and instantly becomes cloudy as microbubbles of primary fine bubbles.
Micro bubbles foamed by the resonant ejector and the resonant foaming device are sent to the secondary pump,
Since the suction capacity of the secondary pump water is several times larger than the water sent from the resonance foaming device due to the effect of the ejector, a vacuum is generated in the entire water system ,
The generated vacuum is the vacuum condition of the entire water system up to the impeller of the pump after the resonant foaming device,
In the meantime, the primary fine bubbles sent from the resonance foaming device are expanded tens of times under vacuum conditions,
Shearing the expanded primary microbubbles by high-speed rotation of the impeller of the secondary pump;
With the impact of hitting the casing with water, it is instantly converted from a vacuum condition to a pressurized condition and crushed.
Nano-sized secondary ultrafine bubbles are generated by vacuum cavitation that breaks by double cavitation action ,
The resulting secondary ultrafine bubbles are crushed by crushing with a crushing device to form nano-sized ultrafine bubbles in which water does not become cloudy,
The water has an oxidizing radical function by the generation of primary fine bubbles by resonance foaming and the two-stage refinement process that generates secondary ultrafine bubbles by vacuum cavitation of the secondary pump ,
Air or oxygen, or wherein the controlling the production of bubble size and a large amount of fine bubbles hyperfine by controlling the output of a single internal combustion engine, the oxidizing radicals of ultra-fine bubble water ozone gas A jet of aqua jet. A hydrogen gas supply device;
Equipped with two sets of internal and internal combustion engine pump devices, each of which is connected to an internal combustion engine and a water flow pump via a clutch,
A primary pump that takes water from a water source;
An apparatus for supplying hydrogen gas;
A resonant ejector that takes in hydrogen gas and mixes and shears with water;
Resonant foaming device that makes the incorporated hydrogen gas into microbubbles,
Arrange the secondary internal combustion engine pump to create a vacuum in order,
The primary internal combustion engine pump takes water from the water source, pressurizes the water, sends it to the resonance ejector,
Hydrogen gas is sent from the gas supply device to the resonance ejector,
The resonance ejector is equipped with a decompression meter, a gas flow meter, a resonance adjustment needle valve, and a resonance foaming device.
Mix the water sent from the primary internal combustion engine pump and the gas sent from the hydrogen gas supply device with a resonance ejector,
At that time, adjust the water and gas supply ratio and pressure reduction with the resonance adjustment needle valve and pressure gauge,
A mixture of water and gas is resonantly foamed with a resonant foaming device and instantly becomes cloudy as microbubbles of primary fine bubbles.
The microbubbles of primary fine bubbles foamed by the resonant ejector and the resonant foaming device are sent to the secondary internal combustion engine pump.
Since the suction capacity of the secondary internal combustion engine pump is several times larger than the water sent from the resonant foaming device due to the effect of the ejector, a vacuum is generated in the entire water system ,
The generated vacuum is the vacuum condition of the entire water system up to the impeller of the pump after the resonant foaming device,
In the meantime, the primary fine bubbles sent from the resonance foaming device are expanded tens of times under vacuum conditions,
The expanded primary fine bubbles are crushed by the vacuum shearing by the high-speed rotation of the impeller of the secondary internal combustion engine engine pump and the function of instantaneously converting the vacuum condition from the vacuum condition to the pressurizing condition and hitting it.
Nano-sized secondary microbubbles are generated by vacuum cavitation that breaks by double cavitation,
The resulting nanobubbles are crushed by crushing with a crushing device, and there are ultra-fine nano-sized fine bubbles where water does not become cloudy,
An aqua-jet device for jetting ultra-fine bubble water of hydrogen, wherein the output of an internal combustion engine is controlled to control the bubble size and the amount of fine bubbles produced. The aqua jet device according to claim 1, claim 2, or claim 3, wherein the engine of the internal combustion engine of the aqua jet device that ejects air, oxygen or ultrafine bubble water of ozone gas is a gasoline engine, Using an engine that can be used for any fuel such as propane engine, alcohol engine and diesel engine,
Ultra-fine, characterized by using an engine that can be used for any fuel such as a gasoline engine, a propane engine, an alcohol engine, and a diesel engine as an engine of an aqua jet device that ejects hydrogen ultra-fine bubbles. Aqua jet device that blows out bubble water.