KR102666271B1 - Liquid fertilizer manufacturing device using gas-selective generators and microbubble generating device - Google Patents

Abstract

In the present invention, power is applied through the control unit 90 of the gas selection generator (A) to form a power switch 16 that is connected and energized, and an oxygen dissolved water operation number button ( 11), the nitrogen dissolved water operation frequency button (12), the atmospheric dissolved water operation frequency button (13), and the ozone dissolved water operation frequency button (14) are formed, respectively, and the time setting button (17) from 1 to 24 is formed. a setting unit (10); It is a compressed storage tank in which compressed gas flows into the inside and is compressed and stored by the compressor 23. It is connected to the setting unit 10, and a gas inlet hole 21 through which the compressed gas flows inside is formed on one side, On the other side, a gas discharge hole 22 is formed to discharge the internal compressed gas to the outside, and is connected to the atmospheric dissolved water operation count button 13 of the setting unit 10, and the atmospheric dissolved water operation count button 13 If the number of times pressed and entered is "0", the compressor (23) does not operate, and if the number of times pressed and entered by the standby dissolved water operation number button (13) is "1" or more, the compressor (23) does not operate. A gas storage tank (20) that operates to perform the process of suctioning and compressing the surrounding air in one cycle, thereby executing the cycle as many times as the number of times input by pressing the atmospheric dissolved water operation number button (13); It is connected to the oxygen dissolved water operation count button 11 of the setting unit 10, and if the number of times pressed and entered by the oxygen dissolved water operation count button 11 is "0", it does not operate, and the oxygen dissolved water operation It operates when the number of times entered by pressing the number button (11) is "1" or more, sucks and compresses the surrounding air, transfers it to the adsorption bed (not shown), and compresses only oxygen in the adsorption bed to a concentration of 90% or more. An oxygen generator that performs the process of separately discharging other gases, including nitrogen, while supplying them to the gas storage tank 20 in one cycle, thereby executing the cycle as many times as the number of operations pressed and entered by the oxygen dissolved water operation number button 11. 30); It is connected to the nitrogen dissolved water operation count button 12 of the setting unit 10, and when the number of times pressed and entered by the nitrogen dissolved water operation count button 12 is "0", the compressor 23 does not operate. , When the number of times entered by pressing the nitrogen dissolved water operation number button (12) is "1" or more, the compressor (23) operates, sucks in surrounding air, and fills the tank with oxygen adsorbent (CMS) (not shown). The nitrogen dissolved water operation number button is performed in one cycle by supplying only nitrogen at a concentration of 90% or more into the water tank 70 through the supply pipe 81 while separately discharging the oxygen adsorbed on the oxygen adsorbent (CMS). A nitrogen generator (40) that is pressed by (12) and executes the cycle the number of times entered; It is connected to the ozone dissolved water operation count button 14 of the setting unit 10, and when the number of times pressed and entered by the ozone dissolved water operation count button 14 is "0", the compressor 23 does not operate. , When the number of times entered by pressing the ozone dissolved water operation number button 14 is "1" or more, the compressor 23 operates, and suctions and compresses the surrounding air using the oxygen generator 30 to form an adsorption bed ( (not shown), and generates concentrated oxygen of more than 90% of oxygen in the adsorption bed, receives the concentrated oxygen thus generated, changes the oxygen into ozone through a silent discharge action, and supplies it to the supply pipe 81. An ozone generator (60) that executes the cycle as many times as entered by pressing the ozone dissolved water operation number button (14) by performing one cycle; As a body in which water (74) is supplied and stored, an upper water level sensor (71) and a lower water level sensor (72) are formed, and the upper water level sensor (71) is raised and lowered according to the required amount of water for the crop, so that when fully charged, the upper water level sensor (71) is raised and lowered. A water tank (70) that controls the water level and supply amount of (74) and has a pump (73) on one side that supplies dissolved water to crops; It is installed at the bottom of the water tank 70 and connected to the gas storage tank 20 and the supply pipe 81, so that the supplied gas is generated as microbubbles inside the water tank 70, and the water 74 is dissolved in the gas. Microbubble generator (80) that converts water (75); And the capacity of the water tank 70 required for crops is set by the interval between the upper and lower water level sensors 71 and 72, and the inside of the water tank 70 is filled with water 74 according to the set capacity, necessary for crop growth. Accordingly, the oxygen dissolved water operation count button 11, the nitrogen dissolved water operation count button 12, the ammonia dissolved water operation count button 12a, the standby dissolved water operation count button 13, and the nitric acid dissolved water operation count button 13 of the setting unit 10. The number of water tank operations pre-entered through the dissolved water operation number button 13a and the ozone dissolved water operation number button 14 are recognized, respectively, and the oxygen generator 30 and nitrogen generator 40 are activated according to the input number of water tank operation times. , the compressor (23) and the ozone generator (60) are each sequentially operated to sequentially receive various gases into the gas storage tank (20), which are then returned to the microbubble generator (80) in the water (74) inside the water tank (70). ) by generating microbubbles, the water (74) is sequentially converted into various dissolved waters (75) such as oxygen dissolved water, nitrogen dissolved water, ammonia dissolved water, atmospheric dissolved water, nitric acid dissolved water, and ozone dissolved water. A gas selection generator having a control unit 90 that sequentially executes the number of water tank operations for one cycle supplied to the crops through (73) by the number of water tank operations input in advance and sequentially supplies the dissolved sap ratio necessary for crop growth; This relates to a liquid fertilizer manufacturing device using a microbubble generating device.
The present invention uses a gas selective generator and a microbubble generator to supply oxygenated water rich in dissolved oxygen to crops by irrigation and side spraying to smoothly induce the growth of aerobic microorganisms and suppress harmful bacteria and aerobic microorganisms. It achieves a balance of fungi in the soil and medium or in hydroponic and aquaponics farming methods, improves root development of crops during crop growth, and increases the proliferation rate of aerobic microorganisms when harvesting crops, thereby activating crop root development and growth. Yields can be further increased, and nitrogen-dissolved water rich in dissolved nitrogen is supplied to crops to increase yield more smoothly through the photosynthetic action of leaves using crowns and phloem from fine roots, thereby improving growth growth and crop yield. By supplying ammonium-dissolved water rich in dissolved ammonia to crops, fine roots that obtain nitrogen-fixing bacteria from root nodule bacteria can maximize the effect of nitrogen fertilizer absorption and help crops with proteins and nucleic acids necessary for glucose production. It contributes to the creation of fertile land by propagating bacteria beneficial to the growth of fine roots, and dissolved atmospheric water, which is rich in dissolved air, ionizes the greenhouse gas carbon dioxide and supplies it to crops, allowing crops to grow continuously in a well-balanced state. By supplying nitrate-dissolved water rich in dissolved nitric acid to crops, it induces aerobic fungal growth of nitrifying bacteria important for nitrogen assimilation and further maximizes plant-based conditions for glucose, protein, and nucleic acid to increase harvest. It plays a role in maintaining the balance of important bacterial reproduction and becomes a nature-friendly circulation method that is repeated in the gaseous atmosphere through denitrification, and supplies ozone-dissolved water rich in dissolved ozone to crops, eliminating mold, insects, bacteria, and viruses. It has the effect of killing, suppressing, and avoiding treatment, oxidizing and decomposing heavy metals, activating root development and growth of crops, and sustainably increasing crop yield at low cost.

Description

Liquid fertilizer manufacturing device using gas-selective generators and microbubble generating device}

The present invention relates to a method of manufacturing liquid fertilizer using a gas selective generator and a microbubble generator. More specifically, the present invention relates to a method of irrigating crops with oxygenated water rich in dissolved oxygen using a gas selective generator and a microbubble generator. By supplying it through side spraying, it smoothly induces the growth of aerobic microorganisms, suppresses harmful bacteria and aerobic microorganisms, achieves a balance of fungi in soil and media, or in hydroponic and aquaponics farming methods, and improves root development of crops when growing crops. By increasing the proliferation rate of aerobic microorganisms when harvesting crops, the root development and growth of crops are activated, thereby increasing crop yield. By supplying nitrogen-dissolved water rich in dissolved nitrogen to crops, they use crowns and phloem from fine roots. By inducing the yield to increase more smoothly through the photosynthetic action of the leaves, growth growth and crop yield can be further increased, and by supplying ammonium-dissolved water rich in dissolved ammonia to the crops, fine roots obtain nitrogen-fixing bacteria from root nodule bacteria. It maximizes the effect of nitrogen fertilizer absorption, helps crops with the proteins and nucleic acids needed to produce glucose, and propagates bacteria beneficial to the growth of fine roots, contributing to the creation of fertile land. By ionizing gas carbon dioxide and supplying it to crops, it induces continuous growth in a well-balanced state of crop growth and growth, and by supplying nitrate-dissolved water rich in dissolved nitric acid to crops, aerobic fungi of nitrifying bacteria, which are important in nitrogen assimilation, are used. It plays a role in maintaining the balance of important bacterial reproduction that further maximizes the plant-based conditions of glucose, proteins, and nucleic acids to induce proliferation and increase harvest, and is a natural and friendly circulation method that is repeated into the gaseous atmosphere by denitrification. By supplying ozone-dissolved water rich in dissolved ozone to crops, it kills, suppresses, and evades mold, insects, bacteria, and viruses, and oxidizes and decomposes heavy metals to activate root development and growth of crops, thereby increasing crop yield. This relates to a liquid fertilizer manufacturing device using a gas selective generator and a microbubble generator that can be sustainably increased at low cost.

In general, organic fertilizer is a relative concept with inorganic fertilizer (chemical fertilizer), and includes organic fertilizers made from organic matter as the main raw material and by-product fertilizers made from by-products as the main raw material. Raw materials for such organic or by-product fertilizers include boiled bran, ash, These include manure residue, humus soil, amino acid fermentation by-product fertilizer, composted rice husk, sawdust, or soil microbial agents.

Among them, most chemical fertilizers are fast-acting, dissolving quickly when applied to the soil, and the soil is temporarily enriched with nutrients immediately after application. However, plants cannot absorb or utilize nutrients applied in a short period of time all at once. As a result, the remaining nutrients that plants cannot absorb seep into the soil, causing contamination of soil, groundwater, and rivers.

Our country's soil suffers from poor crop growth, poor quality, and reduced disease resistance due to long-term fertilization with chemical fertilizers, excessive use of pesticides and chemical herbicides, and continuous cultivation of one crop. , causing crop contamination, reduced yield, and decreased productivity.

In addition, the use of concentrated chemical fertilizers and pesticides can cause serious salt accumulation, and the antagonistic effect between excessively sprayed nutrients can cause chain disorders due to mineral deficiencies, etc., resulting in reduced disease resistance of crops and poor growth. Problems such as decreased harvest and decreased quality and taste also occurred.

Recently, as agricultural pollution problems have become more serious along with environmental pollution problems, the development of agricultural methods that use high-quality organic fertilizers or mature compost rather than chemical fertilizers or pesticides has spread, and the development of many organic fertilizers has been continuously attempted. there is.

However, despite these efforts, the intensive use of organic fertilizers and compost, which are used as alternatives to chemical fertilizers, is deepening another problem that is similar to chemical agents, with only material differences. Soil acidity affects many things, including the characteristics of the soil itself, the availability of nutrients, and microbial activity, and especially has a significant impact on nutrient absorption, which is closely related to the growth of crops.

Therefore, in order to improve the growth of crops, many attempts are being made to change acidic farmland to alkaline farmland to neutral (PH 6.5~7) farmland. In general, quicklime fertilizer, slaked lime fertilizer, and dolomite fertilizer (gosoil) are used. A large amount of lime-based and sulfur-based substances containing calcium and sulfur, such as fertilizers), gypsum fertilizers, and shellfish fertilizers (shell powder fertilizers), are used as soil improvement fertilizers.

However, because the calcium (Ca) and sulfur (S) contained in lime-based and sulfur-based fertilizers can harden the soil, the large-scale use of lime-based or sulfur-based fertilizers alone is gradually being avoided. Accordingly, there is a need to develop fertilizers that have the effect of improving the growth of crops while solving these side effects. In particular, the demand for fertilizers using natural products is increasing.

In order to solve this problem, "mixed solution preparation step (S100) of preparing a mixed solution by dissolving materials including sodium metasilicate, potassium phosphate, potassium carbonate, and citric acid in water; willow, orientalis, mugwort, and citric acid, A natural material preparation and mixing step (S200) of preparing and mixing natural materials including dandelion, dandelion, and Houttuynia cordata (S300); fermenting the mixed natural materials (S300); A natural extract manufacturing step (S400) of mixing and then further fermenting to produce a microbial activator (S500) and mixing the natural extract and the microbial activator to produce a liquid fertilizer; It includes a liquid fertilizer manufacturing step (S600) of preparing a liquid fertilizer, and in the mixed solution manufacturing step (S100), the mixed solution contains 70 to 100 parts by weight of sodium metasilicate, 60 to 90 parts by weight of potassium phosphate, and carbonic acid for 1000 parts by weight of the total water. It is prepared by mixing 15 to 25 parts by weight of potassium and 1 to 2 parts by weight of citric acid and then stirring, and in the natural material preparation and mixing step (S200), the prepared natural materials are willow, cypress, mugwort, and Siberian ginseng. , dandelion, and Houttuynia cordata are mixed at a weight ratio of 1:1:1:1:1:1:1, respectively, and in the natural material fermentation step (S300), the microorganism is Rhizopus oligosporus. ) or Saccharomyces cerevisiae, one or more microorganisms selected from among are used, the microorganisms are mixed at a weight ratio of 1 to 3 parts by weight based on 100 parts by weight of the mixed natural material, and the natural extract In the manufacturing step (S400), the fermented natural material is mixed at a weight ratio of 30 to 50 parts by weight with respect to the total 100 parts by weight of the mixed solution, and then fermentation is further carried out for 5 to 10 days at a temperature of 45 to 50 ° C. to produce a natural extract. In the liquid fertilizer manufacturing step (S600), the liquid fertilizer is prepared by mixing 100 to 200 parts by weight of natural extract and 10 to 30 parts by weight of microbial activator. Plant root growth. “Method for manufacturing liquid fertilizer for promotion.” Patent registration No. 10-2118923 (2020.06.04. It had been commenced with a notice).

However, these conventional liquid fertilizers require a lot of additional time and money in the process of purchasing and collecting many types of natural ingredients and fermenting them, so they have financial problems that make it difficult to use them universally in farms. there was.

(Patent Document 1) (KR) Republic of Korea Patent Registration No. 10-2118923 (announced on June 4, 2020)

The present invention is intended to solve the above problems, and uses a gas selective generator and a microbubble generator to smoothly induce the growth of aerobic microorganisms by supplying oxygenated water rich in dissolved oxygen to crops through irrigation and side spraying. By suppressing harmful bacteria and aerobic microorganisms, it achieves a balance of fungi in soil and media or hydroponic and aquaponics farming methods, improves root development of crops when growing crops, and increases the proliferation rate of aerobic microorganisms when harvesting crops, thereby improving crop growth. By activating root development and growth, crop yield can be further increased, and by supplying nitrogen-dissolved water rich in dissolved nitrogen to crops, the yield can be more smoothly increased through the photosynthetic action of leaves using crowns and phloem from fine roots. By inducing it as much as possible, growth growth and crop yield can be further increased, and by supplying ammonium-dissolved water rich in dissolved ammonia to crops, fine roots obtained from nitrogen-fixing bacteria from root nodule bacteria can maximize the effect of nitrogen fertilizer absorption, and the crop can It provides proteins and nucleic acids necessary for glucose production and contributes to the creation of fertile land by propagating bacteria to benefit the growth of fine roots. Dissolved atmospheric water, which is rich in dissolved air, ionizes the greenhouse gas carbon dioxide and supplies it to crops, contributing to crop growth and growth. It induces continuous growth in a well-balanced state, supplies crops with nitrate-dissolved water rich in dissolved nitric acid, induces aerobic fungal growth of nitrifying bacteria important for nitrogen assimilation, and provides glucose, protein, and It plays a role in maintaining the balance of important bacterial reproduction that further maximizes the plant-based conditions of nucleic acids, and becomes a nature-friendly circulation method that is repeated into the gaseous atmosphere by denitrification, and supplies ozone-dissolved water rich in dissolved ozone to crops. Selective gas generation that kills, suppresses, and repels fungi, insects, bacteria, and viruses, oxidizes and decomposes heavy metals, and activates root development and growth of crops while sustainably increasing crop yield at low cost. The purpose is to provide a liquid fertilizer manufacturing device using a device and a microbubble generating device.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

In order to achieve this purpose, the present invention is formed with a power switch 16 that is connected and energized when power is applied, and an oxygen dissolved water operation number button 11 and a nitrogen dissolved water operation number button 11 that is input by separately adding or subtracting the number of times it is pressed. The operation count button (12), the standby dissolved water operation count button (13), and the ozone dissolved water operation count button (14) are formed respectively, and the setting unit (10) is formed with a time setting button (17) from 1 to 24. ;

It is a compressed storage tank in which compressed gas flows into the inside and is compressed and stored by the compressor 23. It is connected to the setting unit 10, and a gas inlet hole 21 through which the compressed gas flows inside is formed on one side, On the other side, a gas discharge hole 22 is formed to discharge the internal compressed gas to the outside, and is connected to the atmospheric dissolved water operation count button 13 of the setting unit 10, and the atmospheric dissolved water operation count button 13 If the number of times pressed and entered is "0", the compressor (23) does not operate, and if the number of times pressed and entered by the standby dissolved water operation number button (13) is "1" or more, the compressor (23) does not operate. A gas storage tank (20) that operates to perform the process of suctioning and compressing the surrounding air in one cycle, thereby executing the cycle as many times as the number of times input by pressing the atmospheric dissolved water operation number button (13);

It is connected to the oxygen dissolved water operation count button 11 of the setting unit 10, and when the number of times pressed and entered by the oxygen dissolved water operation count button 11 is "0", the compressor 23 does not operate. When the number of times entered by pressing the oxygen dissolved water operation number button (11) is “1” or more, the compressor (23) operates, sucks and compresses the surrounding air, transfers it to the adsorption bed (not shown), and stores it in the adsorption bed. The process of compressing only oxygen to a concentration of 90% or more and supplying it to the gas storage tank (20) while separately discharging other gases, including nitrogen, is performed in one cycle, and is input by pressing the oxygen dissolved water operation count button (11). An oxygen generator (30) that executes the cycle the specified number of times;

It is connected to the nitrogen dissolved water operation count button 12 of the setting unit 10, and when the number of times pressed and entered by the nitrogen dissolved water operation count button 12 is "0", the compressor 23 does not operate. , When the number of times entered by pressing the nitrogen dissolved water operation number button (12) is "1" or more, the compressor (23) operates, sucks in surrounding air, and fills the tank with oxygen adsorbent (CMS) (not shown). The nitrogen dissolved water operation number button is performed in one cycle by supplying only nitrogen at a concentration of 90% or more into the water tank 70 through the supply pipe 81 while separately discharging the oxygen adsorbed on the oxygen adsorbent (CMS). A nitrogen generator (40) that is pressed by (12) and executes the cycle the number of times entered;

It is connected to the ozone dissolved water operation count button 14 of the setting unit 10, and when the number of times pressed and entered by the ozone dissolved water operation count button 14 is "0", the compressor 23 does not operate. , When the number of times entered by pressing the ozone dissolved water operation number button 14 is "1" or more, the compressor 23 operates, and suctions and compresses the surrounding air using the oxygen generator 30 to form an adsorption bed ( (not shown), and generates concentrated oxygen of more than 90% of oxygen in the adsorption bed, receives the concentrated oxygen thus generated, changes the oxygen into ozone through a silent discharge action, and supplies it to the supply pipe 81. An ozone generator (60) that executes the cycle as many times as entered by pressing the ozone dissolved water operation number button (14) by performing one cycle;

As a body in which water (74) is supplied and stored, an upper water level sensor (71) and a lower water level sensor (72) are formed, and the upper water level sensor (71) is raised and lowered according to the required amount of water for the crop, so that when fully charged, the upper water level sensor (71) is raised and lowered. A water tank (70) that controls the water level and supply amount of (74) and has a pump (73) on one side that supplies dissolved water to crops;

It is installed at the bottom of the water tank 70 and connected to the gas storage tank 20 and the supply pipe 81, so that the supplied gas is generated as microbubbles inside the water tank 70, and the water 74 is dissolved in the gas. Microbubble generator (80) that converts water (75); and

The capacity of the water tank 70 required for crops is set by the interval between the upper and lower water level sensors 71 and 72, and the inside of the water tank 70 is filled with water 74 according to the set capacity to meet the needs of crop growth. Therefore, in advance through the oxygen dissolved water operation count button 11, the nitrogen dissolved water operation count button 12, the standby dissolved water operation count button 13, and the ozone dissolved water operation count button 14 of the setting unit 10. Each input number of water tank operations is recognized, and the oxygen generator (30), nitrogen generator (40), compressor (23), and ozone generator (60) are sequentially operated according to the input number of water tank operations to sequentially produce various gases. This is received into the gas storage tank 20 and supplied to the microbubble generator 80 in the water 74 inside the water tank 70 to generate microbubbles, thereby sequentially converting the water 74 into oxygen dissolved water and nitrogen. It is made of various dissolved water (75) such as dissolved water, atmospheric dissolved water, and ozone dissolved water and supplied to the crops through the pump (73). The number of tank operations for one cycle is sequentially performed as many as the number of tank operations entered in advance to grow crops. It has the feature of being provided with a control unit 90 that sequentially supplies the dissolved sap ratio required for.

It is connected to the nitric acid dissolved water operation count button 13a of the setting unit 10, and when the number of times pressed and entered by the nitric acid dissolved water operation count button 13a is "0", the compressor 23 does not operate. , When the number of times input by pressing the nitric acid dissolved water operation number button (13a) is "1" or more, the compressor (23) operates, sucks in and compresses the surrounding air, and supplies it to the gas storage tank (20), When the nitric acid dissolved water operation button (13a) is pressed, the nitrogen chain consisting of a triple bond is separated by the plasma generator (13aa), which generates high temperature and high pressure like an air discharge (lightning), and enters the water tank (70) through the supply pipe (81). It has the feature of further comprising a nitric acid dissolved water operation count button (13a) that executes the cycle as many times as the number of times pressed and entered by the nitric acid dissolved water operation count button (13a) by carrying out the process of generating nitric acid dissolved water in one cycle. .

It is connected to the ammonia dissolved water operation count button 12a of the setting unit 10, and when the number of times pressed and entered by the ammonia dissolved water operation count button 12a is "0", the compressor 23 does not operate. , When the number of times the ammonia dissolved water operation number button (12a) is pressed and entered is "1" or more, the compressor (23) operates, sucks in the surrounding air, and fills the tank with oxygen adsorbent (CMS) (not shown). While passing through, only nitrogen at a concentration of 90% or more is supplied into the water tank 70 through the supply pipe 81, while oxygen adsorbed on the oxygen adsorbent (CMS) is separated and discharged separately, and a hydrogen generator located inside the water tank 70 ( When electrolysis occurs by operating 12aa), the oxygen from + is released into the air, and ammonium ion nitrogen dissolved water is generated using the catalyst (12ab) reaction, and the surrounding air is sucked in by the compressor (23) to create an oxygen adsorbent. A process of supplying only nitrogen at a concentration of 90% or more into the water tank 70 through the supply pipe 81 while passing through a tank (not shown) full of CMS, while separately discharging oxygen adsorbed on the oxygen adsorbent (CMS). It has the feature of further including an ammonia operation count button (12a) that executes the cycle as many times as the input number by pressing the ammonia dissolved water operation count button (12a) by performing one cycle.

The oxygen generator has the characteristic of collecting only the remaining nitrogen after generating compressed oxygen and storing it in a separate nitrogen storage tank.

The nitrogen generator has the characteristic of collecting only the oxygen adsorbed on the oxygen adsorbent (CMS) after generating compressed nitrogen and storing it in a separate oxygen storage tank.

The microbubble generator is,

An underwater motor located in the water tank and having a rotation axis;

a bubble generating rotating plate, which is a circular plate having an axis hole coupled to the rotating shaft and a plurality of bubble generating protrusions that are partially cut and bent downward;

A rotary plate case in which a circular cylindrical body with an open top is formed on the lower surface of which a closed shaft hole having a sealing ring for supporting the rotating shaft is sealed and the bubble generating rotating plate is located inside the upper surface;

A case fixing member in which a plurality of rotary plate cases having the bubble generating rotating plate are tightly stacked at the top and bottom, and rigidly supports this stacked state; and

Compressed gas is supplied at a certain pressure by connecting the supply pipe of the gas storage tank to the lowermost rotating plate case among the plurality of rotating plate cases fixed and supported by the case holding device or to the case holding device that fixedly supports the lowest rotating plate case. It has the characteristic of being supplied inside the rotating plate case.

The case fixing district is,

Among the rotary plate cases, which are plate-shaped rectangular plates with multiple plates stacked at the top and bottom, the bottom of the rotary plate case on the lowermost side has a seating recess that is tightly seated, has a shaft through-hole formed in a sealed manner in the center of the seating recess, and has a bottom fastening hole formed through the upper and lower portions at the four directions. Bottom fastening support panels each having a;

Among the rotating plate cases, which are plate-shaped rectangular parallelepipeds with a plurality of plates stacked top and bottom, the uppermost rotating plate case has a seating recess that is sealed and seated, and has upper fastening holes formed at the upper and lower portions on the extension line of the lower fastening holes at the four diagonal ends, and one upper surface. An upper fastening support panel having a microbubble ejection gap at or above that is in fine communication with the seating recess and through which internal microbubbles are ejected to the outside; and

It is characterized by providing fastening bolts that are respectively screwed and fixed to the lower fastening holes of the lower fastening support panel through the upper fastening holes of the four directions of the upper fastening support panel.

The rotating shaft of the underwater motor of the microbubble generator is characterized in that the power transmission direction is changed by 180 degrees through a gearbox, and the power is transmitted to each of the bubble generating rotating plates of the plurality of rotating plate cases stacked and fixed by the case fixing device.

The gearbox is,

A drive gear located on an extension line of the underwater motor rotation axis and having a drive shaft that is shaft-coupled and extends;

An interlocking gear that is horizontally engaged with the drive gear and has an interlocking shaft at the center of the upper surface;

A lower gear panel having a rectangular plate body with a certain thickness, an upper surface having a gear groove for supporting the driving gear and the interlocking gear, and a ring groove on the outside of the gear groove into which a sealing ring is inserted; and

It is a rectangular plate body with a certain thickness that is located on the upper part of the lower gear panel and is sealed and fastened to it. It has a drive shaft hole through which the drive shaft of the drive gear protrudes to be sealed to the top, and the interlocking shaft of the interlocking gear protrudes to be sealed to the top. It has the characteristic of being provided with an upper gear panel having an axial hole.

An inlet pipe is further formed on one side of the upper surface of the upper gearbox of the gearbox, which communicates with the gear part of the lower gear panel and allows water from the water tank to flow into the inside through a filter, and the other end of the supply pipe of the gas storage tank is connected to the inlet pipe. It is coupled, and one end is pipe-connected to communicate with the gear recess on the other side of the upper surface of the upper gearbox, and the other end is pipe-connected to communicate with the inside of the lowermost rotating plate case seated in the seating recess of the lower fastening support panel, so that water and gas are stacked in a plurality. It has the characteristic of being provided with a joint supply pipe that supplies to the rotating plate case.

In addition, the present invention provides a power switch 16 that is connected and energized by applying power through the control unit 90 of the gas selection generator (A), and an oxygen dissolved water operation number button whose number of presses is separately added or subtracted. (11), the nitrogen dissolved water operation count button (12), the standby dissolved water operation count button (13), and the ozone dissolved water operation count button (14) are formed respectively, and the time setting button (17) from 1 to 24 is formed. A setting unit 10 is formed;

It is connected to the oxygen dissolved water operation count button 11 of the setting unit 10, and if the number of times pressed and entered by the oxygen dissolved water operation count button 11 is "0", it does not operate, and the oxygen dissolved water operation It operates when the number of times entered by pressing the number button (11) is "1" or more, sucks and compresses the surrounding air, transfers it to the adsorption bed (not shown), and compresses only oxygen in the adsorption bed to a concentration of 90% or more. An oxygen generator (30) that performs the process of separately discharging other gases, including nitrogen, in one cycle while supplying them to the supply pipe (81), thereby executing the cycle as many times as the number of operations pressed and entered by the oxygen dissolved water operation number button (11); .

It is connected to the nitrogen dissolved water operation count button 12 of the setting unit 10, and when the number of times pressed and entered by the nitrogen dissolved water operation count button 12 is "0", it does not operate, and the nitrogen dissolved water operation It operates when the number of times pressed and entered by the number button 12 is "1" or more, sucking in the surrounding air and passing it through a tank (not shown) full of oxygen adsorbent (CMS), producing only nitrogen at a concentration of 90% or more. While supplying the oxygen adsorbed to the oxygen adsorbent (CMS) into the water tank 70 through the supply pipe 81, the process of separating and discharging the oxygen is performed in one cycle, so that the nitrogen dissolved water operation number is pressed and entered as many times as the button 12. A nitrogen generator (40) that runs the cycle;

It is connected to the ozone dissolved water operation count button 14 of the setting unit 10, and when the number of times pressed and entered by the ozone dissolved water operation count button 14 is "0", it does not operate, and the ozone dissolved water operation It operates when the number of times pressed and entered by the number button 14 is "1" or more, and uses the oxygen generator 30 to inhale and compress the surrounding air, transfer it to the adsorption bed (not shown), and The process of generating more than 90% concentrated oxygen using only oxygen, receiving the concentrated oxygen thus generated, changing the oxygen into ozone through a silent discharge action, and supplying it to the supply pipe 81 is performed in one cycle, thereby increasing the number of ozone-dissolved water operations. An ozone generator (60) that executes the cycle by pressing the button (14) the number of times entered;

As a body in which water (74) is supplied and stored, an upper water level sensor (71) and a lower water level sensor (72) are formed, and the upper water level sensor (71) is raised and lowered according to the required amount of water for the crop, so that when fully charged, the upper water level sensor (71) is raised and lowered. A water tank (70) that controls the water level and supply amount (74) and has a pump (73) on one side that supplies dissolved water to crops;

It is installed at the bottom of the water tank 70 and connected to the gas storage tank 20 and the supply pipe 81, so that the supplied gas is generated as microbubbles inside the water tank 70, and the water 74 is dissolved in the gas. Microbubble generator (80) that converts water (75); and

The capacity of the water tank 70 required for crops is set by the interval between the upper and lower water level sensors 71 and 72, and the inside of the water tank 70 is filled with water 74 according to the set capacity to meet the needs of crop growth. Therefore, the oxygen dissolved water operation count button 11, the nitrogen dissolved water operation count button 12, the ammonia dissolved water operation count button 12a, the standby dissolved water operation count button 13, and the nitric acid dissolved water operation count button 13 of the setting unit 10. By recognizing the number of water tank operations pre-entered through the water operation number button 13a and the ozone dissolved water operation number button 14, the oxygen generator 30, the nitrogen generator 40, By operating the ozone generators 60 sequentially, various gases are sequentially supplied to the microbubble generator 80 in the water 74 inside the water tank 70 through the supply pipe 81 to generate microbubbles, thereby generating water ( 74) is sequentially made into various dissolved waters (75) such as oxygen dissolved water, nitrogen dissolved water, ammonia dissolved water, atmospheric dissolved water, nitric acid dissolved water, and ozone dissolved water, and then supplied to crops through the pump (73). It is characterized by having a control unit 90 that sequentially executes the number of water tank operations as the number of water tank operations entered in advance and sequentially supplies the dissolved sap ratio necessary for crop growth.

In this way, the present invention uses a gas selective generator and a microbubble generator to supply oxygenated water rich in dissolved oxygen to crops by irrigation and side spraying, thereby smoothly inducing the growth of aerobic microorganisms and eliminating harmful bacteria and aerobic microorganisms. It suppresses the balance of fungi in soil and media or hydroponic and aquaponics farming methods, improves root development of crops when growing, and increases the proliferation rate of aerobic microorganisms when harvesting crops, activating root development and growth of crops. It is possible to further increase crop yield, and by supplying nitrogen-dissolved water rich in dissolved nitrogen to crops, it induces the growth and growth of crops to be increased more smoothly through the photosynthetic action of leaves using crowns and phloem from fine roots. Yields can be further increased, and by supplying ammonium-dissolved water rich in dissolved ammonia to crops, fine roots obtained with nitrogen-fixing bacteria from root nodule bacteria can maximize the effect of nitrogen fertilizer absorption, and proteins and nucleic acids necessary for crops to produce glucose. It contributes to the creation of fertile land by propagating bacteria beneficial to the growth of fine roots, and dissolved atmospheric water, which is rich in dissolved air, ionizes the greenhouse gas carbon dioxide and supplies it to crops, maintaining a well-balanced growth and growth of crops. By supplying nitrate-dissolved water rich in dissolved nitric acid to crops, it induces aerobic fungal growth of nitrifying bacteria, which are important for nitrogen assimilation, and provides plant-based conditions of glucose, protein, and nucleic acid to increase harvest. It plays a role in maintaining the balance of important bacterial reproduction and is a nature-friendly circulation method that is repeated in the gaseous atmosphere through denitrification, and supplies ozone-dissolved water rich in dissolved ozone to crops to prevent fungi, insects, and bacteria. It has the effect of killing, suppressing, and avoiding viruses, oxidizing and decomposing heavy metals, activating root development and growth of crops, and sustainably increasing crop yield at a low cost.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, such changes are within the scope of the claims.

1 is a schematic diagram showing a liquid fertilizer manufacturing device using a gas selective generator and a microbubble generator, which is an embodiment of the present invention;
Figure 2 is an exploded perspective view showing the connection of the microbubble generating device of the liquid fertilizer manufacturing device using the gas selective generating device and the microbubble generating device, which is an embodiment of the present invention;
Figure 3 is a combined perspective view showing the front side of the microbubble generator of the liquid fertilizer manufacturing device using the gas selective generator and microbubble generator, which is an embodiment of the present invention;
Figure 4 is a combined perspective view showing the rear side of the microbubble generator of the liquid fertilizer manufacturing device using the gas selective generator and microbubble generator, which is an embodiment of the present invention;
Figure 5 is a cross-sectional view of the main part of the microbubble generator of the liquid fertilizer manufacturing device using the gas selective generator and microbubble generator according to an embodiment of the present invention;
Figure 6 is a schematic diagram showing the operation of another embodiment of the liquid fertilizer production device using the gas selection generator and the microbubble generator according to the present invention, with the compressor and gas storage tank excluded.

Hereinafter, the present invention will be described in more detail with the accompanying drawings.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention in the drawings, parts not related to the description are omitted, and identical or similar components are given the same reference numerals throughout the specification. The scope of rights of the present invention should not be construed as being limited by the embodiments described in the text, and since the embodiments can be modified in various ways and may have various forms, the scope of rights of the present invention should not be construed as limited by the embodiments described in the text. It should be understood to include equivalents.

Throughout the specification of the present invention, when a part is said to be “connected” to another part, this includes not only “directly connected” but also “indirectly connected” through another member. Additionally, when a part is said to “include” a certain component, this means that it may further include other components, rather than excluding other components, unless specifically stated to the contrary.

The terms used in the present invention are terms defined in consideration of the functions in the present invention, and may vary depending on the intention or custom of the user or operator, so the definitions of these terms are defined in accordance with the technical details of the present invention. It should be interpreted as a concept.

Additionally, optional terms in the examples below are used to distinguish one component from another component, and the components are not limited by the terms. Hereinafter, in describing the present invention, detailed descriptions of related known technologies that may unnecessarily obscure the gist of the present invention will be omitted.

The liquid fertilizer manufacturing device using the gas selection generator and microbubble generator of the present invention includes a setting unit (10), a compressor (23), a gas storage tank (20), an oxygen generator (30), a nitrogen generator (40), and A gas selection generator (A) including an ozone generator (60), a water tank (70), and a control unit (90), which receives the gas and converts the water (74) in the water tank (70) into dissolved water (75) in which the gas is dissolved. It consists of a microbubble generator (80) that converts.

The setting unit 10 is formed with a power switch 16 through which power is applied and connected and energized, and an oxygen dissolved water operation count button 11 and a nitrogen dissolved water operation count button ( 12), the atmospheric dissolved water operation frequency button 13 and the ozone dissolved water operation frequency button 14 are formed, respectively, and the time setting button 17 from 1 to 24 is formed.

The gas storage tank 20 is a compressed storage tank in which compressed gas flows into the inside and is compressed and stored by the compressor 23. It is connected to the setting unit 10 and has a gas tank on one side through which the compressed gas flows inside. An inlet hole 21 is formed, and on the other side, a gas discharge hole 22 is formed to discharge the internal compressed gas to the outside, and the gas storage tank 20 is the atmospheric dissolved water of the setting unit 10. It is connected to the operation count button (13), and when the number of times entered by pressing the standby dissolved water operation count button (13) is "0", the compressor (23) does not operate, and the standby dissolved water operation count button (13) If the number of times pressed and entered is "1" or more, the compressor (23) operates and performs the process of suctioning and compressing the surrounding air in one cycle, thereby increasing the number of times pressed and entered by the atmospheric dissolved water operation number button (13). Run the cycle as much as

The nitric acid dissolved water operation count button 13a is connected to the nitric acid dissolved water operation count button 13a of the setting unit 10, and the number of times pressed and entered by the nitric acid dissolved water operation count button 13a is "0. " In this case, the compressor (23) does not operate, and if the number of times entered by pressing the nitric acid dissolved water operation number button (13a) is "1" or more, the compressor (23) operates and sucks in the surrounding air. It is compressed and supplied to the gas storage tank (20), and when the nitric acid dissolved water operation number button (13a) is pressed, the nitrogen link consisting of a triple bond is separated by the plasma generator (A13aa), which generates high temperature and high pressure like an air discharge (lightning). The process of generating nitric acid dissolved water while supplying it into the water tank 70 through the supply pipe 81 is performed in one cycle, thereby executing the cycle as many times as the number of times input by pressing the nitric acid dissolved water operation number button 13a.

The oxygen generator 30 is connected to the oxygen dissolved water operation count button 11 of the setting unit 10, and when the number of times pressed and entered by the oxygen dissolved water operation count button 11 is “0”, If the compressor (23) does not operate and the number of times entered by pressing the oxygen dissolved water operation number button (11) is "1" or more, the compressor (23) operates, sucks in and compresses the surrounding air, and forms an adsorption bed (as shown). ), compressing only oxygen to a concentration of 90% or more in the adsorption bed, supplying it to the gas storage tank (20), and separately discharging other gases, including nitrogen, in one cycle, thereby increasing the number of times the oxygen dissolved water is operated. The button 11 is pressed to execute the cycle the number of times entered. Of course, it is preferable that the oxygen generator 30 collects only the remaining nitrogen after generating compressed oxygen and stores it in a separate nitrogen storage tank (not shown).

The nitrogen generator 40 is connected to the nitrogen dissolved water operation count button 12 of the setting unit 10, and when the number of times pressed and entered by the nitrogen dissolved water operation count button 12 is "0", The compressor (23) does not operate, and when the number of times entered by pressing the nitrogen dissolved water operation number button (12) is "1" or more, the compressor (23) operates, sucks in the surrounding air, and produces oxygen adsorbent (CMS). The process of supplying only nitrogen at a concentration of 90% or more into the water tank 70 through the supply pipe 81 while passing through a tank (not shown) full of oxygen, and separately separating and discharging oxygen adsorbed on the oxygen adsorbent (CMS), is one cycle. By performing this, the nitrogen dissolved water operation number button (12) is pressed and the cycle is executed as many times as the entered number. Of course, it is preferable that the nitrogen generator 40 collects only the oxygen adsorbed on the oxygen adsorbent (CMS) after generating nitrogen and stores it in a separate oxygen storage tank (not shown).

The ammonia dissolved water operation count button 12a is connected to the ammonia dissolved water operation count button 12a of the setting unit 10, and the number of times pressed and entered by the ammonia dissolved water operation count button 12a is "0. " In this case, the compressor (23) does not operate, and if the number of times pressed and entered by the ammonia dissolved water operation number button (12a) is "1" or more, the compressor (23) operates, sucking in the surrounding air and producing oxygen. While passing through a tank (not shown) filled with an adsorbent (CMS), only nitrogen at a concentration of 90% or more is supplied into the water tank 70 through the supply pipe 81, while the oxygen adsorbed on the oxygen adsorbent (CMS) is separated and discharged separately. When electrolysis occurs by operating the hydrogen generator (12aa) located inside the water tank (70), oxygen from + is released into the air, and ammonium ion nitrogen dissolved water is generated using the catalyst (12ab) reaction, and the compressor ( 23), the surrounding air is sucked in and passed through a tank (not shown) filled with an oxygen adsorbent (CMS), and only nitrogen at a concentration of 90% or more is supplied into the water tank 70 through the supply pipe 81, and the oxygen adsorbent (CMS) is supplied to the inside of the water tank 70 through the supply pipe 81. The process of separating and discharging the oxygen adsorbed on the CMS) is performed in one cycle, thereby executing the cycle as many times as the number entered by pressing the ammonia dissolved water operation number button (12a).

The ozone generator 60 is connected to the ozone dissolved water operation count button 14 of the setting unit 10, and when the number of times pressed and input by the ozone dissolved water operation count button 14 is “0”, The compressor 23 does not operate, and when the number of times the ozone dissolved water operation number button 14 is pressed and entered is "1" or more, the compressor 23 operates and uses the oxygen generator 30 to purify the surrounding area. The air is sucked and compressed and transferred to an adsorption bed (not shown), and concentrated oxygen of more than 90% of oxygen is generated within the adsorption bed. The concentrated oxygen thus generated is received and the oxygen is changed into ozone through a silent discharge action, thereby producing the above-mentioned oxygen. By carrying out the process of supplying to the supply pipe 81 in one cycle, the cycle is executed as many times as the ozone-dissolved water operation number button 14 is pressed and entered.

The water tank 70 is a cylinder in which water 74 is supplied and stored, and an upper water level sensor 71 and a lower water level sensor 72 are formed, and the upper water level sensor 71 is configured according to the required amount of water for crops. By raising and lowering the water level and supply amount of water 74 when fully charged, a pump 73 is formed on one side to supply dissolved water to crops.

The microbubble generator 80 is installed at the bottom of the water tank 70 and is connected to the gas storage tank 20 and the supply pipe 81 to generate the supplied gas into microbubbles inside the water tank 70 to create water. (74) is converted into dissolved water (75) in which gas is dissolved.

The microbubble generator 80 is located in the water tank 70 and has a submersible motor 85 having a rotating shaft 85a, and a shaft hole 82b that is axially coupled to the rotating shaft 85a and is partially cut out. A bubble generating rotating plate 82, which is a circular plate having a plurality of bubble generating protrusions 82a bent downward, and a sealing ring 83b on the lower side of which the rotating shaft 85a is sealed and axially supported, which is a circular cylinder with an open top. ) is formed with a closed shaft hole (83a) and the rotating plate case (83) in which the bubble generating rotating plate (82) is located inside the upper surface, and a plurality of rotating plate cases (83) having the bubble generating rotating plate (82) are located on the upper and lower sides. A case fixing member 84 that is stacked in a sealed manner and firmly supports the stacked state, and the lowest rotating plate case 83 or the lowest of a plurality of rotating plate cases 83 fixed and supported by the case holding device 84. The supply pipe 81 of the gas storage tank 20 is connected to the case fixing support 84 that connects and supports the side rotating plate case 83 to supply compressed gas into the rotating plate case 83 at a certain pressure. It comes true.

The case fixing member 84 is a plate-shaped rectangular parallelepiped and has a seating recess 84aa on which the lower part of the lowermost rotating plate case 83 is seated in a sealed manner among the plurality of rotary plate cases 83 stacked top and bottom, and a seating recess 84aa. ) A lower fastening support panel (84a) having an axial through hole (84ab) formed to be airtight in the center and lower fastening holes (84ac) formed at the top and bottom at the four diagonal ends, and a rotating plate in which a plurality of plate-shaped rectangular parallelepipeds are stacked at the top and bottom. Among the cases 83, the uppermost rotating plate case 83 has a seating recess 84ba that is seated in a sealed manner, and upper fastening holes 84bb are formed at the upper and lower portions on the extension lines of the lower fastening holes 84ac at the four directions. An upper fastening support panel (84b) having a fine bubble ejection gap (84bc) on at least one upper surface that is in fine communication with the seating recess (84ba) through which internal fine bubbles are ejected to the outside, and the upper fastening support panel ( 84b) It is provided with fastening bolts 84c that are respectively screwed and fixed to the lower fastening holes 84ac of the lower fastening support panel 84a through the upper fastening holes 84bb at the four diagonal ends.

The rotating shaft 85a of the underwater motor 85 of the microbubble generator 80 has a power transmission direction changed by 180 degrees through the gearbox 86, and a plurality of units are stacked and fixed by the case fixing member 84. Power is transmitted to each bubble generating rotating plate (82) of the rotating plate case (83).

The gearbox 86 includes a drive gear 86a having a drive shaft 86aa that is located on the extension line of the rotation shaft 85a of the underwater motor 85 and is axially coupled and extends, and a drive gear 86a horizontally aligned with the drive gear 86a. An interlocking gear (86b) that is gear-coupled and has an interlocking shaft (86ba) at the center of the upper surface, and a gear element (86ca) that is a square plate with a certain thickness and supports the driving gear (86a) and the interlocking gear (86b) on the upper surface. It has a lower gear panel (86c) with a ring groove (86cb) into which a sealing ring (86cc) is inserted on the outside of the gear groove (86ca), and a certain thickness that is located on the upper part of the lower gear panel (86c) and is tightly fastened. It is a square plate body having a drive shaft hole 86da through which the drive shaft 86aa of the drive gear 86a protrudes in a sealed manner upward, and a drive shaft hole 86da through which the interlocking shaft 86ba of the interlocking gear 86b protrudes sealedly upward. It consists of an upper gear panel (86d) with an axial hole (86db).

One side of the upper surface of the upper gear panel (86d) of the gear box (86) is in communication with the gear portion (86ca) of the lower gear panel (86c), so that water (74) of the water tank (70) flows into the inside through a filter (87a). An inflow pipe 87 is further formed.

The other end of the supply pipe 81 of the gas storage tank 20 is connected to the inflow pipe 87.

One end is pipe-connected to the gear recess (86ca) on the other side of the upper surface of the upper gear panel (86d), and the other end is connected to the inside of the lowermost rotating plate case (83) seated on the seating recess (84aa) of the lower fastening support panel (84a). A joint supply pipe (88) is formed by connecting pipes in communication to supply water (74) and gas to a plurality of stacked rotary plate cases (83).

The control unit 90 sets the capacity of the water tank 70 required for crops by the interval between the upper and lower water level sensors 71 and 72, and fills the water tank 70 with water 74 according to the set capacity. Depending on the needs of crop growth, the oxygen dissolved water operation count button 11, the nitrogen dissolved water operation count button 12, the ammonia dissolved water operation count button 12a, and the atmospheric dissolved water operation count button 11 of the setting unit 10. By recognizing the number of water tank operations pre-entered through the button 13, the nitric acid dissolved water operation number button 13a, and the ozone dissolved water operation number button 14, the oxygen generator 30 is activated by the number of water tank operations entered. , the nitrogen generator (40), compressor (23), and ozone generator (60) are each sequentially operated to sequentially receive various gases into the gas storage tank (20) and return them to the water (74) inside the water tank (70). By generating microbubbles by supplying water to the microbubble generator 80, water 74 is sequentially converted into various dissolved waters such as oxygen dissolved water, nitrogen dissolved water, ammonia dissolved water, atmospheric dissolved water, nitric acid dissolved water, and ozone dissolved water. (75), the number of water tank operations for one cycle supplied to the crops through the pump (73) is sequentially executed as the number of water tank operations entered in advance, and the dissolved sap ratio required for crop growth is sequentially supplied.

This present invention operates by releasing the pressure of the compressor 23 when the user presses the power switch 16. In the control unit 90 of the gas selection generator (A), the user selects the crop according to the needs of the crop. The capacity of the water tank 70 set by the water level detection sensors 71 and 72 is recognized, the inside of the water tank 70 is filled with water 74 according to the set capacity of the water tank 70, and the gas storage tank ( 20) The compressed gas inside is released into the atmosphere through the gas discharge hole (22) while making a whistling sound.

Next, the user presses the oxygen number button 11, nitrogen number button 12, ammonia number button 12a, standby number button 13, and nitric acid number button 13a of the setting unit 10 according to the needs of the crop. ), press the ozone count button (14) to enter the number of times the water tank is operated, and press the time setting button (17) to set the time from 1 to 24 hours. At this time, 1 is set to 30 minutes, 7 is set to 3 hours and 30 minutes, 12 is set to 6 hours, and 20 is set to 10 hours.

At this time, in the setting unit 10 of the gas selection generator A, the user sets the oxygen dissolved water operation number button 11 to “3”, the nitrogen dissolved water operation number button 12 to “2”, and the ammonia dissolved water operation number button 12 to “2.” The operation count button (12a) is “0”, the atmospheric dissolved water operation count button (13) is “1”, the nitric acid dissolved water operation count button (13a) is “0”, and the ozone dissolved water operation count button (14) is “0”. This explanation assumes that it is set to “1”.

Then, the control unit 90 of the gas selection generator (A) sucks the surrounding air through the oxygen generator 30 according to “3” of the oxygen dissolved water operation number button 11 and creates an adsorption bed (not shown). The oxygen is compressed to a concentration of 90% or more in the adsorption bed and supplied to the gas storage tank (20), while other gases, including nitrogen, are separated and discharged separately, and the oxygen stored in the gas storage tank (20) is transferred to the compressor. It is supplied to the microbubble generator (80) in the water (74) inside the water tank (70) through the supply pipe (81) at a pressure of (23).

At this time, oxygen supplied into the inlet pipe 87 through the supply pipe 81 of the microbubble generator 80 is supplied to the gearbox ( It is supplied at a certain pressure into the lowermost rotating plate case (83) located in the seating groove (84aa) of the lower fastening support panel (84a) through the gear groove (86ca) of 86) and the joint supply pipe (88).

Accordingly, the microbubble generator 80 rotates the rotation shaft 85a of the underwater motor 85 to rotate the drive gear 86a inside the gearbox 86, and then engages the drive gear 86a again. As the interlocking gear (86b) is rotated, the interlocking shaft (86ba) is also rotated, and a plurality of extension shafts (86bb) that are axially coupled to the interlocking shaft (86ba) and extend upward are stacked by the case fixing member (84). By rotating the bubble generating rotating plate (82) inside the fixed rotating plate case (83), the water (74) and oxygen introduced through the joint supply pipe (88) are transferred to the plurality of bubble generating protrusions (82a) of the rotating rotating plate (82). It is transferred to the upper rotating plate case (83) by hitting it multiple times, and microbubbles are generated through a process of dissolving water (74) and oxygen in multiple stages, and the microbubbles created in this way are connected to the upper fastening support panel (84b). As it is ejected into the water tank 70 through a plurality of fine bubble ejection gaps 84bc formed in , the fine bubbles containing dissolved oxygen convert the water 74 inside the water tank into dissolved oxygen water.

In this way, the water tank 70 filled with oxygen-dissolved water is operated for one cycle of oxygen-dissolved water supplied to crops through the pump 73.

In this way, the number of oxygen-dissolved water operations for one cycle as described above is sequentially repeated as many as the pre-entered number "3", and the oxygen-dissolved sap ratio is sequentially supplied to the crops three times, thereby promoting root establishment and growth of the crops.

Next, by the control unit 90, the inside of the water tank 70 is filled with water 74, and according to the water tank operation number "2" of the nitrogen dissolved water operation number button 12, the nitrogen generator 40 By inhaling and compressing the surrounding air, passing through a tank (not shown) filled with an oxygen adsorbent (CMS), only nitrogen is compressed to a concentration of 90% or more and supplied to the gas storage tank 20, and the oxygen adsorbent (CMS) is supplied to the gas storage tank 20. The oxygen adsorbed is separated and discharged separately, and the nitrogen stored in the gas storage tank (20) is discharged from the microbubble generator (80) in the water (74) inside the water tank (70) through the supply pipe (81) under the pressure of the compressor (23). ) is supplied.

The nitrogen supplied to the microbubble generator 80 in this way is ejected into the water tank 70 through the fine bubble ejection gap 84bc through the same process as above, and the fine bubbles in which the compressed nitrogen is dissolved are released into the water inside the water tank ( 74) is converted into nitrogen-dissolved water.

At this time, the water tank 70 filled with nitrogen dissolved water is operated for one cycle of nitrogen dissolved water supplied to crops through the pump 73, and is sequentially repeated as many times as the pre-entered number "2" to produce nitrogen as above. By supplying dissolved sap to crops sequentially twice, the photosynthetic action of crops is induced more smoothly and the yield of crops can be increased.

Next, if the state in which the user sets the ammonia button 12a is “0”, the process proceeds to the next step.

Next, by the control unit 90, the inside of the water tank 70 is filled with water 74, and according to “1” of the standby dissolved water operation number button 13, the compressor 23 creates the atmosphere. The collected air is compressed and stored in the gas storage tank (20) by sucking and compressing the surrounding air, and the compressed air is supplied to the microbubble generator (80) through the supply pipe (81). The air supplied to (80) goes through the same process as above and is ejected into the water tank (70) through the fine bubble ejection gap (84bc), and the fine bubbles in which the air is dissolved are released into the water (74) inside the water tank (70). It is converted into dissolved atmospheric dissolved water, and the water tank 70 filled with atmospheric dissolved water is operated for one cycle of atmospheric dissolved water supplied to crops through the pump 73, and the pre-entered "1" is performed. " By supplying the atmospheric dissolved sap ratio to the crops once as described above, it induces stable crop growth with well-balanced crop growth.

Next, if the state in which the user sets the nitric acid button 13a is “0”, the process proceeds to the next step.

Next, by the control unit 90, the water tank 70 is filled with water 74, and the ozone generator 60 operates as an oxygen generator according to “1” of the ozone dissolved water operation number button 14. Surrounding air is sucked in through (30), transferred to an adsorption bed (not shown), and only oxygen is concentrated to a concentration of 90% or more within the adsorption bed. The ozone generator (60) receives oxygen in this way and produces oxygen through a silent discharge action. The ozone is converted into ozone and supplied to the microbubble generator 80 through the supply pipe 81, and the ozone supplied to the microbubble generator 80 goes through the same process as above to form the microbubble ejection gap 84bc. As fine bubbles are ejected into the water tank 70, the fine bubbles in which ozone is dissolved convert the water 74 inside the water tank into ozone-dissolved water, and the water tank 70 is filled with ozone-dissolved water. One cycle of ozone-dissolved water supplied to the crops through the pump 73 is performed, and by supplying the pre-entered ozone-dissolved sap ratio of "1" to the crops once, bacteria are removed for smoother growth of the crops. It sterilizes and disinfects viruses and fungi, oxidizes heavy metals, kills dangerous pathogens, and destroys the habitat conditions of insects to encourage them to avoid them, leading to smoother crop growth.

When the water level of the dissolved water 75 in the upper water level sensor 71 of the water tank 70 is full, the microbubble generator 80 operates for a predetermined time and then turns off by the control unit 90.

When the water 74 is full up to the upper water level detection sensor 71 of the water tank 70, the number of operations is recognized, and the next set course is automatically applied as the set number of operation is exceeded, which is determined by the upper water level detection sensor 71. It is operated by

When the water level of the lower water level sensor 72 of the water tank 70 decreases, it stops operating and turns off.

In addition, the liquid fertilizer manufacturing device using the gas selection generator and the microbubble generating device of the present invention is as shown in FIG. 6, even when the compressor 23 and the gas storage tank 20 are excluded from the existing liquid fertilizer manufacturing device. Of course, it can be easily implemented.

Accordingly, the present invention uses a gas selective generator (A) and a microbubble generator (80) to supply oxygenated water rich in dissolved oxygen to crops in an appropriate amount as needed to promote the growth of aerobic microorganisms in the soil of crops. By inducing it more smoothly, the root development of the crop improves during growth, and the growth rate of aerobic microorganisms is increased when harvesting the crop, thereby activating growth at the same time as the root development of the crop, thereby increasing crop yield.

In addition, by supplying an appropriate amount of nitrogen-dissolved water, which is rich in dissolved nitrogen, to crops as needed, photosynthesis through leaves can be induced more smoothly, thereby further increasing growth and crop yield.

In addition, by supplying ammonia-dissolved water rich in dissolved ammonia to the crops in appropriate amounts as needed, the fine roots obtained from the root nodule bacteria can maximize the effect of nitrogen fertilizer absorption and provide the proteins and nucleic acids necessary for the crops to produce glucose. It can contribute to the creation of fertile soil by propagating bacteria to benefit the growth of fine roots.

In addition, by supplying an appropriate amount of atmospheric dissolved water, which is rich in dissolved air, to crops, they are encouraged to grow in a well-balanced state.

In addition, nitric acid-rich water rich in dissolved nitric acid is supplied to crops in appropriate amounts as needed to induce aerobic fungal growth of nitrifying bacteria important for nitrogen assimilation and further maximize plant-based conditions for glucose, protein, and nucleic acid to increase harvest. It plays a role in maintaining the balance of important bacterial reproduction and becomes a nature-friendly circulation method that is repeated in the gaseous atmosphere through denitrification.

In addition, by supplying ozone-dissolved water, which is rich in dissolved ozone, to crops in an appropriate amount as needed, it kills or repels mold, insects, bacteria, and viruses, and oxidizes and decomposes heavy metals to activate root development and growth of crops. Yields can be increased sustainably at low cost.

This embodiment and the drawings attached to this specification only clearly show a part of the technical idea included in the present invention, and those skilled in the art can easily infer within the scope of the technical idea included in the specification and drawings of the present invention. It is obvious that all possible modifications and specific embodiments are included within the scope of the technical idea of the present invention.

The scope of the present invention is indicated by the claims described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and the equivalent concept should be construed as being included in the scope of the present invention.

A: Gas selection generator
10: Setting section
11: Oxygen dissolved water operation count button
12: Nitrogen dissolved water operation count button
12a ; Ammonia operation count button
12aa: Hydrogen generator
12ab: catalyst
13: Standby dissolved water operation count button
13a: Nitric acid operation number button
13aa: Plasma generator
14: Ozone dissolved water operation count button
16: Power switch
17: Time setting button
20: Gas storage tank
21: Gas inlet hole
22: Gas exhaust hole
23: Compressor
30: Oxygen generator
40: nitrogen generator
60: Ozone generator
70: Water tank
71: Upper water level sensor
72: Lower water level sensor
73: pump
74: water
75: Dissolved water
80: Microbubble generator
81: supply pipe
90: control unit

Claims (13)

A setting unit 10 having a power switch 16 and a compressed storage tank in which compressed gas flows into the inside and is compressed and stored by the compressor 23 are connected to the setting unit 10, and on one side, the compressed gas flows inside. A gas storage tank (20) in which an inflowing gas inlet hole (21) is formed and on the other side a gas discharge hole (22) that discharges the internal compressed gas to the outside is formed, and an adsorption bed (shown) that suctions and compresses the surrounding air. an oxygen generator (30) that compresses only oxygen to a concentration of 90% or more in the adsorption bed and supplies it to the gas storage tank (20), a nitrogen generator (40) that supplies nitrogen, and a nitrogen generator (40) that supplies ozone. An ozone generator 60, a water tank 70 in which a pump 73 for supplying dissolved water to crops is formed on one side of the body in which water 74 is supplied and stored, and a microbubble generator that generates microbubbles ( 80) and a control unit 90 that controls the operation of the oxygen generator 30, nitrogen generator 40, compressor 23, and ozone generator 60. Liquid phase using a gas selection generator and a microbubble generator In the fertilizer manufacturing device,
The setting unit 10 is an oxygen dissolved water operation number button that is connected and energized by applying power through the control unit 90 of the gas selection generator (A) through the power switch 16, and the number of times it is pressed is separately added or subtracted. (11), the nitrogen dissolved water operation frequency button (12), the atmospheric dissolved water operation frequency button (13), and the ozone dissolved water operation frequency button (14) are formed respectively, and the time setting button (17) from 1 to 24 is formed. become;
The gas storage tank 20 is connected to the standby dissolved water operation count button 13 of the setting unit 10, and when the number of times pressed and entered by the standby dissolved water operation count button 13 is “0”. The compressor (23) does not operate, and when the number of times the standby dissolved water operation number button (13) is pressed and entered is "1" or more, the compressor (23) operates to start the process of suctioning and compressing the surrounding air. By performing one cycle, the cycle is executed as many times as the number of times entered by pressing the standby dissolved water operation number button (13);
The oxygen generator 30 is connected to the oxygen dissolved water operation count button 11 of the setting unit 10, and when the number of times pressed and entered by the oxygen dissolved water operation count button 11 is "0", It does not operate, and operates when the number of times entered by pressing the oxygen dissolved water operation number button (11) is "1" or more. The process of separately discharging other gases, including nitrogen, after supplying oxygen from the adsorption bed is one cycle. By performing this, the cycle is executed as many times as the number of times entered by pressing the oxygen dissolved water operation number button 11;
The nitrogen generator 40 is connected to the nitrogen dissolved water operation count button 12 of the setting unit 10, and when the number of times pressed and entered by the nitrogen dissolved water operation count button 12 is “0”, The compressor (23) does not operate, and if the number of times entered by pressing the nitrogen dissolved water operation number button (12) is "1" or more, the compressor (23) operates, sucks in the surrounding air, and produces oxygen adsorbent (CMS). The process of supplying only nitrogen at a concentration of 90% or more into the water tank 70 through the supply pipe 81 while passing through a tank (not shown) full of oxygen, and separately separating and discharging the oxygen adsorbed on the oxygen adsorbent (CMS), is one cycle. By performing this, the cycle is executed as many times as the number of times entered by pressing the nitrogen dissolved water operation number button 12;
The ozone generator 60 is connected to the ozone dissolved water operation count button 14 of the setting unit 10, and when the number of times pressed and entered by the ozone dissolved water operation count button 14 is “0”, The compressor 23 does not operate, and when the number of times entered by pressing the ozone dissolved water operation number button 14 is "1" or more, the compressor 23 operates and uses the oxygen generator 30 to purify the surrounding area. The air is sucked and compressed and transferred to an adsorption bed (not shown), and concentrated oxygen of more than 90% of oxygen is generated within the adsorption bed. The concentrated oxygen thus generated is received and the oxygen is changed into ozone through a silent discharge action, thereby producing the above-mentioned oxygen. The process of supplying to the supply pipe (81) is performed in one cycle, thereby executing the cycle as many times as the ozone-dissolved water operation number button (14) is pressed and entered;
The water tank 70 is formed with an upper water level sensor 71 and a lower water level sensor 72, so that the upper water level sensor 71 is raised and lowered according to the required amount of water for the crops, thereby raising and lowering the water level of the water 74 when fully charged. and regulating supply;
The microbubble generator 80 is installed at the bottom of the water tank 70 and is connected to the gas storage tank 20 and the supply pipe 81 to generate the supplied gas into microbubbles inside the water tank 70. Converting water (74) into dissolved water (75) in which gas is dissolved;
The control unit 90 sets the capacity of the water tank 70 required for crops by the interval between the upper and lower water level sensors 71 and 72, and fills the water tank 70 with water 74 according to the set capacity. Depending on the needs of crop growth, the oxygen dissolved water operation count button 11, the nitrogen dissolved water operation count button 12, the ammonia dissolved water operation count button 12a, and the atmospheric dissolved water operation count button 11 of the setting unit 10. By recognizing the number of water tank operations pre-entered through the button 13, the nitric acid dissolved water operation number button 13a, and the ozone dissolved water operation number button 14, the oxygen generator 30 is activated by the number of water tank operations entered. , the nitrogen generator (40), compressor (23), and ozone generator (60) are each sequentially operated to sequentially receive various gases into the gas storage tank (20) and return them to the water (74) inside the water tank (70). By generating microbubbles by supplying water to the microbubble generator 80, water 74 is sequentially converted into various dissolved waters such as oxygen dissolved water, nitrogen dissolved water, ammonia dissolved water, atmospheric dissolved water, nitric acid dissolved water, and ozone dissolved water. Gas selection characterized by sequentially supplying the dissolved sap ratio necessary for crop growth by sequentially executing the number of tank operations for 1 cycle supplied to the crops through the pump (73) as the number of tank operations entered in advance. Liquid fertilizer manufacturing device using a generator and a microbubble generator. According to claim 1,
It is connected to the nitric acid dissolved water operation count button 13a of the setting unit 10, and when the number of times pressed and entered by the nitric acid dissolved water operation count button 13a is "0", the compressor 23 does not operate. , When the number of times input by pressing the nitric acid dissolved water operation number button (13a) is "1" or more, the compressor (23) operates, sucks in and compresses the surrounding air, and supplies it to the gas storage tank (20), When the nitric acid dissolved water operation button (13a) is pressed, the nitrogen chain consisting of a triple bond is separated by the plasma generator (13aa), which generates high temperature and high pressure like an air discharge (lightning), and enters the water tank (70) through the supply pipe (81). The process of generating nitric acid dissolved water while supplying it is performed in one cycle, and is further provided with a nitric acid dissolved water operation count button (13a) that executes the cycle as many times as the number of times pressed and entered by the nitric acid dissolved water operation count button (13a). A liquid fertilizer manufacturing device using a gas selective generator and a microbubble generator. According to claim 1,
It is connected to the ammonia dissolved water operation count button 12a of the setting unit 10, and when the number of times pressed and entered by the ammonia dissolved water operation count button 12a is "0", the compressor 23 does not operate. , When the number of times the ammonia dissolved water operation number button (12a) is pressed and entered is "1" or more, the compressor (23) operates, sucks in the surrounding air, and fills the tank with oxygen adsorbent (CMS) (not shown). While passing through, only nitrogen at a concentration of 90% or more is supplied into the water tank 70 through the supply pipe 81, while oxygen adsorbed on the oxygen adsorbent (CMS) is separated and discharged separately, and a hydrogen generator located inside the water tank 70 ( When electrolysis occurs by operating 12aa), the oxygen from + is released into the air, and ammonium ion nitrogen dissolved water is generated using the catalyst (12ab) reaction, and the surrounding air is sucked in by the compressor (23) to create an oxygen adsorbent. A process of supplying only nitrogen at a concentration of 90% or more into the water tank 70 through the supply pipe 81 while passing through a tank (not shown) full of CMS, while separately discharging oxygen adsorbed on the oxygen adsorbent (CMS). A gas selection generator and a microbubble generator further comprising an ammonia operation number button (12a) that executes the cycle as many times as the number of times pressed and input by the ammonia dissolved water operation number button (12a) by performing one cycle. Liquid fertilizer manufacturing device used. delete delete According to claim 1,
The microbubble generator 80,
An underwater motor (85) located in the water tank (70) and having a rotation axis (85a);
A bubble generating rotating plate (82), which is a circular plate having a shaft hole (82b) coupled to the rotating shaft (85a) and a plurality of bubble generating protrusions (82a) that are partially cut and bent downward;
It is a circular cylinder with an open top, and a sealed shaft hole (83a) is formed on the lower surface and has a sealing ring (83b) that is supported while sealing the rotating shaft (85), and a rotating plate in which the bubble generating rotating plate (82) is located inside the upper surface. Case (83);
A plurality of rotary plate cases (83) having the bubble generating rotary plate (82) are stacked in a sealed manner at the top and bottom, and a case fixing member (84) that firmly supports this stacked state; and
The lowermost rotating plate case 83 or the lowermost rotating plate case 83 among the plurality of rotating plate cases 83 fixed and supported by the case holding device 84 is connected to the case holding device 84. A liquid fertilizer manufacturing device using a gas selection generator and a microbubble generator, characterized in that compressed gas is supplied into the rotating plate case (83) at a certain pressure by connecting the supply pipe (81) of the gas storage tank (20). According to claim 6,
The case fixing district 84 is,
The lower part of the rotary plate case 83, which is a plate-shaped rectangular parallelepiped with a plurality of plates stacked top and bottom, has a seating concave portion 84aa into which the lower portion is sealed, and an axial through hole (84aa) formed to be sealed in the center of the seating concave portion 84aa. a lower fastening support panel (84a) having 84ab) and lower fastening holes (84ac) formed in the upper and lower portions at the four directions;
Among the rotating plate cases 83, which are formed of a plurality of plate-shaped rectangular parallelepipeds stacked top and bottom, the uppermost rotating plate case 83 has a seating recess 84ba that is hermetically seated, and the upper and lower portions of the upper and lower portions of the lower fastening hole 84ac are provided at the four-way end portion. Each of the top fastening support panels has an upper fastening hole (84bb) formed through a hole, and has a fine bubble ejection gap (84bc) on at least one upper surface that is finely communicated with the seating recess (84ba) through which internal fine bubbles are ejected to the outside. (84b); and
The upper fastening support panel (84b) is provided with fastening bolts (84c) that are respectively screwed and fixed to the lower fastening holes (84ac) of the lower fastening support panel (84a) through the upper fastening holes (84bb) at the four-directional ends of the upper fastening support panel (84b). A liquid fertilizer manufacturing device using a gas selective generator and a microbubble generator, characterized by: According to claim 6,
The rotating shaft 85a of the underwater motor 85 of the microbubble generator 80 has a power transmission direction changed by 180 degrees through the gearbox 86, and a plurality of units are stacked and fixed by the case fixing member 84. A liquid fertilizer manufacturing device using a gas selection generator and a microbubble generator, characterized in that power is transmitted to the bubble generating rotating plate (82) of the rotating plate case (83) through an extension shaft (86bb). According to claim 8,
The gearbox 86 is,
A driving gear (86a) located on an extension line of the rotating shaft (85a) of the underwater motor (85) and having a driving shaft (86aa) that is axially coupled and extends;
An interlocking gear (86b) that is horizontally gear-coupled with the driving gear (86a) and has an interlocking shaft (86ba) at the center of the upper surface;
It is a square plate body with a certain thickness, and has a gear concave portion (86ca) on the upper surface that supports the driving gear (86a) and the interlocking gear (86b), and a ring groove (86cc) into which a sealing ring (86cc) is inserted on the outside of the gear concave portion (86ca). a lower gear panel (86c) having 86cb; and
It is a rectangular plate body with a certain thickness that is located on the upper part of the lower gear panel 86c and is fastened and fixed in a sealed manner, and has a drive shaft hole 86da through which the drive shaft 86aa of the drive gear 86a protrudes in a sealed manner upward and is interlocked with the lower gear panel 86c. Liquid fertilizer using a gas selection generator and a microbubble generator, characterized in that the interlocking shaft 86ba of the gear 86b is provided with an upper gear panel 86d having an interlocking shaft hole 86db that protrudes to be sealed upward. Manufacturing equipment. According to clause 9,
One side of the upper surface of the upper gear box (86d) of the gear box (86) is in communication with the gear portion (86ca) of the lower gear panel (86c), so that the water (74) of the water tank (70) flows into the inside through the filter (87a). An inflow pipe 87 is further formed, and the other end of the supply pipe 81 of the gas storage tank 20 is pipe-coupled with the inflow pipe 87, and one end is connected to a gear buckle ( 86ca), and the other end is connected to the inside of the lowermost rotating plate case 83 seated in the seating recess 84aa of the lower fastening support panel 84a, so that a plurality of water 74 and gas are stacked. A liquid fertilizer manufacturing device using a gas selection generator and a microbubble generator, characterized by having a joint supply pipe (88) that supplies to the rotating plate case (83). A setting unit 10 having a power switch 16, an oxygen generator 30 that suctions and compresses surrounding air, transfers it to an adsorption bed (not shown), and compresses and supplies only oxygen to a concentration of 90% or more within the adsorption bed. A nitrogen generator (40) that supplies nitrogen, an ozone generator (60) that supplies ozone, and a pump (73) that supplies dissolved water to crops are formed on one side of the tube where water (74) is supplied and stored. a water tank 70, a microbubble generator 80 that generates microbubbles, and a control unit ( 90) In the liquid fertilizer manufacturing device using a gas selective generator and a microbubble generator including,
The setting unit 10 is an oxygen dissolved water operation number button that is connected and energized by applying power through the control unit 90 of the gas selection generator (A) through the power switch 16, and the number of times it is pressed is separately added or subtracted. (11), the nitrogen dissolved water operation frequency button (12), the atmospheric dissolved water operation frequency button (13), and the ozone dissolved water operation frequency button (14) are formed respectively, and the time setting button (17) from 1 to 24 is formed. become;
The oxygen generator 30 is connected to the oxygen dissolved water operation count button 11 of the setting unit 10, and when the number of times pressed and entered by the oxygen dissolved water operation count button 11 is “0”, It does not operate, and operates when the number of times entered by pressing the oxygen dissolved water operation number button (11) is "1" or more, supplying compressed oxygen to the supply pipe (81) and separately discharging other gases, including nitrogen. By performing the requested process in one cycle, the cycle is executed as many times as the number of times entered by pressing the oxygen dissolved water operation number button (11);
The nitrogen generator 40 is connected to the nitrogen dissolved water operation count button 12 of the setting unit 10, and when the number of times pressed and entered by the nitrogen dissolved water operation count button 12 is "0", The compressor (23) does not operate, and when the number of times entered by pressing the nitrogen dissolved water operation number button (12) is "1" or more, the compressor (23) operates, sucks in the surrounding air, and produces oxygen adsorbent (CMS). The process of supplying only nitrogen at a concentration of 90% or more into the water tank 70 through the supply pipe 81 while passing through a tank (not shown) full of oxygen, and separately separating and discharging the oxygen adsorbed on the oxygen adsorbent (CMS), is one cycle. By performing this, the cycle is executed as many times as the number of times entered by pressing the nitrogen dissolved water operation number button 12;
The ozone generator 60 is connected to the ozone dissolved water operation count button 14 of the setting unit 10, and when the number of times pressed and entered by the ozone dissolved water operation count button 14 is “0”, The compressor 23 does not operate, and when the number of times the ozone dissolved water operation number button 14 is pressed and entered is "1" or more, the compressor 23 operates and uses the oxygen generator 30 to purify the surrounding area. The air is sucked and compressed and transferred to an adsorption bed (not shown), and concentrated oxygen of more than 90% of oxygen is generated within the adsorption bed. The concentrated oxygen thus generated is received and the oxygen is changed into ozone through a silent discharge action, thereby producing the above-mentioned oxygen. The process of supplying to the supply pipe (81) is performed in one cycle, thereby executing the cycle as many times as the ozone-dissolved water operation number button (14) is pressed and entered;
The water tank 70 is formed with an upper water level sensor 71 and a lower water level sensor 72, so that the upper water level sensor 71 is raised and lowered according to the required amount of water for the crops, thereby raising and lowering the water level of the water 74 when fully charged. and regulating supply;
The microbubble generator 80 is installed at the bottom of the water tank 70 and is connected to the gas storage tank 20 and the supply pipe 81 to generate the supplied gas into microbubbles inside the water tank 70. Converting water (74) into dissolved water (75) in which gas is dissolved;
The control unit 90 sets the capacity of the water tank 70 required for crops by the interval between the upper and lower water level sensors 71 and 72, and fills the water tank 70 with water 74 according to the set capacity. Depending on the needs of crop growth, the oxygen dissolved water operation count button 11, the nitrogen dissolved water operation count button 12, the ammonia dissolved water operation count button 12a, and the atmospheric dissolved water operation count button 11 of the setting unit 10. By recognizing the number of water tank operations pre-entered through the button 13, the nitric acid dissolved water operation number button 13a, and the ozone dissolved water operation number button 14, the oxygen generator 30 is activated by the number of water tank operations entered. By sequentially operating the nitrogen generator 40 and the ozone generator 60, various gases are sequentially supplied to the microbubble generator 80 in the water 74 inside the water tank 70 through the supply pipe 81. By generating microbubbles, the water 74 is sequentially converted into various dissolved waters 75 such as oxygen dissolved water, nitrogen dissolved water, ammonia dissolved water, atmospheric dissolved water, nitric acid dissolved water, and ozone dissolved water, and the pump 73 is used. Liquid using a gas selection generator and a microbubble generator, characterized in that the number of water tank operations for one cycle supplied to the crops is sequentially carried out as the number of water tank operations entered in advance, and the dissolved sap ratio required for crop growth is sequentially supplied. Fertilizer manufacturing device. According to claim 11,
It is connected to the nitric acid dissolved water operation count button 13a of the setting unit 10, and does not operate when the number of times pressed and entered by the nitric acid dissolved water operation count button 13a is "0", and the nitric acid dissolved water operation count button 13a is connected to the setting unit 10. It operates when the number of times entered by pressing the number button (13a) is "1" or more, sucking and compressing the surrounding air and supplying it, and when the nitric acid dissolved water operation number button (13a) is pressed, high temperature and high pressure like an air discharge (lightning). The plasma generator (13aa) is used to separate the nitrogen chain consisting of a triple bond and supply it to the inside of the water tank (70) through the supply pipe (81). The process of generating dissolved nitric acid water is performed in one cycle, thereby increasing the number of operations of dissolved nitric acid water. A liquid fertilizer manufacturing device using a gas selection generator and a microbubble generator, further comprising a nitric acid dissolved water operation count button (13a) that is pressed by the button (13a) to execute the cycle the number of times input. According to claim 11,
It is connected to the ammonia dissolved water operation count button 12a of the setting unit 10, and when the number of times pressed and entered by the ammonia dissolved water operation count button 12a is "0", it does not operate, and the ammonia dissolved water operation is operated. It operates when the number of times pressed and entered by the number button 12a is "1" or more, sucking in the surrounding air and passing it through a tank (not shown) full of oxygen adsorbent (CMS), producing only nitrogen at a concentration of 90% or more. When supplied into the water tank 70 through the supply pipe 81, the oxygen adsorbed on the oxygen adsorbent (CMS) is separated and discharged separately, and electrolysis is generated by operating the hydrogen generator (12aa) located inside the water tank 70. The oxygen coming from + is released into the air and ammonium ion nitrogen dissolved water is created using a catalyst (12ab) reaction. By sucking in the surrounding air and passing it through a tank (not shown) full of oxygen adsorbent (CMS), 90% By supplying only nitrogen at the above concentration into the water tank 70 through the supply pipe 81 and separately discharging the oxygen adsorbed on the oxygen adsorbent (CMS) in one cycle, the ammonia dissolved water operation number button 12a is performed. A liquid fertilizer manufacturing device using a gas selection generator and a microbubble generator, further comprising an ammonia operation number button (12a) that executes the cycle the number of times pressed and entered.