KR20230069769A - Farmland nano bubble ozone water supply system - Google Patents

Abstract

"A farmland nanobubble ozone water supply device" is disclosed. The "agricultural land nano-bubble ozone water supply device" according to the present invention includes a submersible pump 110 for sucking and discharging water from a water storage tank; A filter 120 for filtering out foreign substances in the water discharged from the submersible pump 110; An air compressor 130 for compressing air to a standard pressure and discharging it; an oxygen generator 140 provided at a rear end of the air compressor 130 and generating oxygen; An ozone generator 150 may be included to generate ozone in the oxygen generated by the oxygen generator 140.
In addition, a mixer 160 in which the water passing through the filter 120 and the ozone supplied from the ozone generator 150 are mixed; a nano-bubble generator 170 for forming nano-bubble ozone water with an increased dissolution rate of ozone by converting the water and ozone mixed in the mixer 160 into nano-bubbles; It is preferable to include a discharge pipe 190 for supplying the nano-bubble ozone water discharged from the nano-bubble generator 170 to farmland.

Description

Farmland nano bubble ozone water supply system

The present invention relates to a farmland nanobubble ozone water supply device, and more particularly, to a farmland nanobubble ozone water supply device that supplies nanobubble ozone water mixed with water in the form of nanobubbles to farmland to sterilize soil and help plant growth. it's about

In general, plants basically need water, oxygen and other gases to grow. Oxygen is the most important gas among various gases required for plant growth. The reason for plowing is to blow air, or oxygen, into the soil. Good soil is a soil with a developed single-grain structure and has water retention and air permeability. This soil creates a pleasant environment for the roots of plants and has a good effect on plant growth. To this end, conventionally, sprinklers, injection hoses, and drip hoses are used to irrigate, so that air is supplied to the root zone (close to the roots) through pores in the soil as water flows into the ground. However, since it simply supplies water in the liquid phase, it has many limitations in improving the oxygen demand required by plants and the three phases of soil (gas phase, solid phase, liquid phase), that is, improving the physical properties of soil.

On the other hand, the leaves of plants absorb carbon dioxide and release oxygen, whereas the roots of plants require oxygen. In addition, if moisture is maintained in the rhizosphere of plants for too long, the activities of microorganisms necessary for food conversion are stopped. In addition, if the soil is dry for too long, nutrients are not formed due to the lack of moisture that helps the activation of microorganisms, even though there is a lot of oxygen in the soil. Therefore, it is good to alternate between wetting and drying the root zone of the plant.

To this end, the conventional cultivation method artificially puts oxygen in a water tank to increase the amount of dissolved oxygen and sprays the water to plants to help the growth of crops. However, these conventional methods not only have limitations in increasing the amount of dissolved oxygen, but also have limitations in spraying so that plants can easily absorb them.

In particular, in the case of facility cultivation such as a vinyl house, since rainfall is blocked and cultivation is intensive throughout the year, the chemical components used as fertilizer are accumulated in the topsoil and increase the salt concentration in the soil, resulting in problems with repeated cropping. Vinyl mulching In cultivation, irrigation and fertilization work is cumbersome and labor intensive, and fertilization and irrigation between rows deteriorate the soil environment and deteriorate quality.

On the other hand, ozone is a colorless gas with a pungent odor and has strong oxidizing power. The oxidative decomposition action of this generator oxygen has sterilizing power 6 times stronger than chlorine, and has the effect of removing bacteria and viruses. .

In addition, ozone has an excellent effect of harmless by reacting with organic substances such as cigarette smoke, other odorous gases, and various harmful organic substances. The used ozone gas itself is completely decomposed into oxygen gradually and is harmless. The ozone concentration half-life is about 10 to 15 hours in air and about 20 to 30 minutes in water.

Ozone has been used safely and in large quantities in various fields starting with large-scale water purification plants in Europe and the United States for over a hundred years.

In addition, soil sterilization pesticides represented by methyl bromide are currently banned in order to suppress the destruction of the ozone layer. Currently, it is impossible to suppress microorganisms that affect plant diseases in the soil through the cultivation period only with disinfection using steam and sunlight. Even if this method is used, not only the labor force used is excessive, but the economic burden is also great. Therefore, there is an urgent need to provide an effective soil sterilization method.

Document 1. Korean Intellectual Property Office, Registration Patent No. 10-1252673 "Wastewater treatment device and method using ozone nanobubbles and swirls"

An object of the present invention is to solve the above-mentioned problems, and to provide a farmland nanobubble ozone water supply device that can effectively directly supply oxygen to farmland, help plants grow, and sterilize soil.

Another object of the present invention is to provide a farmland nano-bubble ozone water supply device that supplies nano-bubble ozone water in the form of nano-bubbles to improve the dissolution rate of ozone in order to maximize the sterilizing power of ozone.

Another object of the present invention is to provide a farmland nanobubble ozone water supply device capable of spraying nanobubble ozone water to the rhizosphere of plants.

The above object of the present invention can be achieved by a farmland nanobubble ozone water supply device. The farmland nanobubble ozone water supply device of the present invention includes a submersible pump 110 for sucking and discharging water from a water storage tank; A filter 120 for filtering out foreign substances in the water discharged from the submersible pump 110; An air compressor 130 for compressing air to a standard pressure and discharging it; an oxygen generator 140 provided at a rear end of the air compressor 130 and generating oxygen; An ozone generator 150 may be included to generate ozone from the oxygen generated by the oxygen generator 140 .

In addition, a mixer 160 in which the water passing through the filter 120 and the ozone supplied from the ozone generator 150 are mixed; a nano-bubble generator 170 for forming nano-bubble ozone water with an increased dissolution rate of ozone by converting the water and ozone mixed in the mixer 160 into nano-bubbles; It is preferable to include a discharge pipe 190 for supplying the nano-bubble ozone water discharged from the nano-bubble generator 170 to farmland.

Farmland nano-bubble ozone water supply device according to the present invention supplies nano-bubble ozone water with improved dissolved ozone to farmland to disinfect and sterilize soil, and supplies oxygen to crops to help crops grow. .

In addition, the farmland nanobubble ozone water supply device according to the present invention can improve the sterilization and disinfection effect of the soil and the oxygen absorption efficiency to the plant roots by directly supplying the nanobubble ozone water to the soil and the roots of crops by burying the distribution pipe underground. There are advantages to being

1 is a schematic diagram schematically showing the configuration of a farmland nanobubble ozone water supply device of the present invention;
2 is an exemplary view showing the process of supplying nano-bubble ozone water to a vinyl house by the farmland nano-bubble ozone water supply device of the present invention;
3 is an exemplary view showing a process in which nanobubble ozone water is supplied to the root zone of crops by the farmland nanobubble ozone water supply device of the present invention;
4 is a view showing the shape of the distribution pipe of the farmland nano-bubble ozone water supply device of the present invention.

Hereinafter, the present invention will be described in detail with reference to preferred embodiments of the present invention and accompanying drawings, but the same reference numerals in the drawings will be described on the premise that they refer to the same components.

When it is said that any one component "includes" another component in the detailed description of the invention or in the claims, it is not construed as being limited to the component alone unless otherwise stated, and other components are not included. It should be understood that more can be included.

1 is a block diagram schematically showing the configuration of a farmland nanobubble ozone water supply device 100 according to the present invention, and FIG. It is an exemplary view showing a process of supplying ozone water.

As shown in FIG. 2, the farmland nanobubble ozone water supply device 100 according to the present invention can be used to supply nanobubble ozone water W1 to the soil inside the greenhouse 20 or the facility, as well as nanobubble ozone water to general farmland. It can also be used to supply bubble ozone water (W1).

Farmland nanobubble ozone water supply device 100 according to the present invention improves the dissolution rate of ozone in water by converting ozone into nanobubbles so that ozone can be put to practical use to solve farmland repeated cropping damage.

Nanobubble ozone water (W1) has a high dissolved oxygen rate, so when supplied to plants, it can significantly increase the amount of oxygen supplied to the roots of plants and improve nutrient intake, thereby promoting growth by about 30%. It also prevents the accumulation of nitrate in plant tissue and maintains a healthy physiological balance, helping plants to naturally resist disease.

In addition, the ozone contained in the nano-bubble ozone water (W1) has an effect of preventing damage from repeated cropping by sterilizing and disinfecting the soil.

The farmland nanobubble ozone water supply device 100 includes a submersible pump 110 for discharging water from a water storage tank 10, a filter 120 for filtering foreign substances in water (W) discharged from the submersible pump 110, and air An air compressor (130) for compressing and discharging to a reference pressure, an oxygen generator (140) provided at the rear end of the air compressor (130) and generating oxygen, and generating ozone from the oxygen generated in the oxygen generator (140). The ozone generator 150, the mixer 160 in which the water passing through the filter 120 and the ozone supplied from the ozone generator 150 are mixed, and the water and ozone mixed in the mixer 160 are nano-bubbled to produce ozone. It includes a nano-bubble generator 170 that improves the dissolution rate and a discharge pipe 190 that supplies the nano-bubble ozone water (W1) discharged from the nano-bubble generator 170 to farmland.

The submersible pump 110 sucks water from the water storage tank 10 and supplies it to the filter 120 . The submersible pump 110 may be installed inside the water tank 10 in which rainwater or tap water is received, or may be installed in a river, dam, reservoir, or the like.

The filter 120 is connected to the submersible pump 110 through a water supply pipe to remove foreign substances included in the water W supplied from the submersible pump 110. The filter 120 removes foreign substances remaining in the water (W) to increase the purity of the nano-bubble ozone water (W1).

The air compressor 130 compresses air to a standard pressure to generate nanobubbles in the nanobubble generator 170 and discharges the compressed air.

The oxygen generator 140 contains oxygen in the air generated by the air compressor 130 and supplies it to the ozone generator 150 so that ozone can be generated. The oxygen generator 140 precisely controls the amount of oxygen supplied to the air by the control of the controller.

The ozone generator 150 is coupled to the rear end of the oxygen generator 140 to generate ozone in oxygen-containing air supplied from the oxygen generator 140 . The ozone generator 150 precisely controls the amount of ozone generated by the control unit to minimize damage to the human body, crops, and farmland.

In the mixer 160, water W passed through the filter 120 and air containing ozone passed through the ozone generator 150 are mixed with each other. The ozone water in which water and ozone are mixed in the mixer 160 flows into the nano bubble generator 170.

The nanobubble generator 170 converts water and ozone mixed into ozone water into nanobubbles. In this way, it is converted into a nanobubble form, and the solubility of ozone in water can be increased.

For the nanobubble generator 170, various well-known methods may be applied. That is, a method using an orifice tube or a Venturi tube, a method in which pressurized air is blown in water through a fine net member or a porous plate, and a method in which vortex water is generated may be used.

The nano-bubble ozone water (W1) generated by the nano-bubble generator 170 is supplied to the discharge pipe 190 through the pressure pump 180. As shown in FIG. 2, the discharge pipe 190 is connected to a plurality of distribution pipes 191 disposed in farmland to supply nano-bubble ozone water W1. The pressure pump 180 controls the discharge pressure so that the nanobubble ozone water W1 can be injected at high pressure through the discharge pipe 190 and the distribution pipe 191 connected thereto.

The nano-bubble ozone water (W1) contains high-concentration ozone through the nano-bubble generator 170 and ozone dissolution technology. Ozone contained in this nano-bubble ozone water (W1) is converted to oxygen after 30 minutes to 1 hour after being supplied to farmland, leaving no secondary residue on the soil, and sterilization of farmland using other methods such as chemicals or soil Compared to doing so, it has the advantage of significantly reducing costs, and is environmentally friendly and has the effect of eliminating carbon emissions.

On the other hand, the farmland nanobubble ozone water supply device 100 of the present invention directly sprays the nanobubble ozone water W1 to the soil layer where crops are planted in order to improve the sterilization and disinfection effect of the soil by increasing the absorption rate of ozone to the soil.

To this end, the discharge pipe 190 is connected to a plurality of distribution pipes 191 disposed to be buried at regular intervals underground in the soil area of a facility such as the vinyl house 20 . The distribution pipe 191 is disposed to be buried within 30 to 50 cm from the ground surface (G) and directly supplies the nano-bubble ozone water (W1) toward the soil and the roots of the planted crops (A). A discharge hole 193 is formed on the surface of the plurality of distribution pipes 191 to spray the nano-bubble ozone water W1 to the soil.

At this time, as shown in FIG. 4, discharge holes 193 are provided at different angles along the longitudinal direction of the distribution pipe 191 to uniformly spray the nano-bubble ozone water W1 in various directions of the soil. In addition, a spray cap 195 is coupled to each discharge hole 193 to prevent soil from flowing into the discharge hole 193 and blocking the discharge hole 193 .

The spray cap 195 is formed in a hemispherical shape as shown, and a plurality of spray holes 195a are formed at regular intervals on the surface. Since the plurality of spray holes 195a are formed on a hemispherical curved surface, the nano-bubble ozone water W1 is uniformly sprayed in various directions of the soil.

Meanwhile, a vibrator (not shown) for applying vibration may be provided on an outer or inner wall surface of the distribution pipe 191 . The vibrator (not shown) is operated by a control signal supplied from the controller and causes vibration to be generated in the distribution pipe 191. The vibration generated on the surface of the distribution pipe 191 is transmitted to the spray cap 195 and the discharge hole 193 to remove soil covering the spray cap 195 and the discharge hole 193 .

As shown in FIG. 3, the nano-bubble ozone water (W1) is sprayed upward from the bottom of the root of the crop (W) planted in farmland, so compared to spraying the nano-bubble ozone water (W1) from the air to the soil, the root Oxygen and nutrient uptake may be increased.

Accordingly, there is an advantage of maximizing sterilization and disinfection of farmland and oxygen supply to crops (W) while reducing the amount of nano-bubble ozone water (W1).

Specifically, by directly injecting ozone into the soil through nano-bubble ozone water (W1), it is possible to prevent and treat soil pathogens such as duty nematodes and root knots caused by continuous cropping during the cultivation period, and soil pathogens such as wilt disease and wear disease that occur right before harvest. . In addition, it is possible to disinfect the soil at any time to create a soil environment good for the growth of crops and to enable continuous cropping without damage to crops.

In addition, oxygen generated by the sterilization action of ozone is directly absorbed by the crops through the roots and directly supplies oxygen necessary for the growth of the crops, thus giving a great help to the growth of plants.

In addition, since ozone and air are mixed and injected together through nano-bubble ozone water, not only oxygen in the air but also nitrogen and other components are directly injected. In this process, nitrogen not only has the effect of providing natural materials to the soil as a material for fertilizer, but is also supplied with water and has the effect of supplying natural organic fertilizer by forming organic substances by meeting numerous microorganisms in the soil.

On the other hand, FIGS. 5 and 6 are exemplary diagrams showing modified examples of spraying nano-bubble ozone water (W1) to farmland from the discharge pipe (190a) of the farmland nano-bubble ozone water supply device 100 of the present invention.

The discharge pipe 190a according to the modified example has the advantage of being easy to expand and contract as a plurality of distribution pipes 191 , 191a and 191b are prefabricated according to the area of farmland.

As shown in FIG. 5, a plurality of branch pipes 190-1 are formed in the discharge pipe 190a along the longitudinal direction, and the plurality of distribution pipes 191, 191a, and 191b are branched by a connection pipe 199. (190-1).

At this time, the branch cap 190-2 is coupled to the branch pipe 190-1 to which the distribution pipes 191, 191a, and 191b are not coupled by the connection pipe 199 to prevent the discharge of the nano-bubble ozone water (W1). .

In addition, insertion nails 197 are fixedly coupled to the plurality of distribution pipes 191 , 191a , and 191b vertically along the longitudinal direction, respectively. The insertion nails 197 are provided vertically so that a worker can easily embed the distribution pipes 191, 191a, and 191b into the lower part of the ground.

A sharp tip 197a is formed at the bottom of the insertion nail 197 to facilitate insertion into the ground.

A stopper 198 is coupled to the top of the insertion nail 197. The stopper 198 is provided to have a certain area in the horizontal direction so that the depth d at which the insertion nail 197 is inserted from the ground G is limited, as shown in FIG. 6 .

That is, the stopper 198 contacts the ground and supports the insertion nail 197 so that it does not sink any more into the ground even if time passes, so that the embedding positions of the distribution pipes 191, 191a, and 191b are fixed.

A first thread 197b is formed at a certain length at the top of the insertion nail 197, and a second thread 198a is formed at the stopper 198, so that the user can insert the stopper 198 according to the desired embedding depth of the insertion nail 197. ) can be adjusted.

Here, as shown in FIG. 6, the distribution pipes 191, 191a, and 191b are buried underground, and the discharge pipe 190a and the branch pipe 190-1 are disposed above ground. The connection pipe 199 is preferably formed in the form of a corrugated pipe to correspond to the depth of the underground where the distribution pipes 191, 191a, and 191b are located.

As described above, the farmland nano-bubble ozone water supply device according to the present invention supplies nano-bubble ozone water with improved ozone dissolved amount to farmland to disinfect and sterilize the soil, and supplies oxygen to crops to increase crop yield. helps with fertility

In addition, the farmland nanobubble ozone water supply device according to the present invention can improve the sterilization and disinfection effect of the soil and the oxygen absorption efficiency to the plant roots by directly supplying the nanobubble ozone water to the soil and the roots of crops by burying the distribution pipe underground. There are advantages to being

The technical idea of the present invention was examined through several examples.

It is obvious that a person skilled in the art to which the present invention pertains can variously modify or change the above-described embodiments from the description of the present invention. In addition, even if not explicitly shown or described, a person skilled in the art may make various modifications from the description of the present invention to the technical idea according to the present invention. is obvious, which still belongs to the scope of the present invention. The above embodiments described with reference to the accompanying drawings are described for the purpose of explaining the present invention, and the scope of the present invention is not limited to these embodiments.

10: water tank 20: vinyl house
100: farmland nanobubble ozone water supply device 110: submersible pump
120: filter 130: compressor
140: oxygen generator 150: ozone generator
160: mixer 170: nano bubble generator
180: pressure pump 190,190a: discharge pipe
190-1: branch pipe 190-2: branch cap
191: distribution pipe 193: discharge hole
195: spray cap 195a: spray hole
197: insertion nail 197a: tip
197b: first thread 198: stopper
198a: second thread 199: connector
A: crops
G: ground surface
W: water
W1: Nano bubble ozone water

Claims (2)

A submersible pump 110 for sucking and discharging water from the reservoir;
A filter 120 for filtering out foreign substances in the water discharged from the submersible pump 110;
An air compressor 130 for compressing air to a standard pressure and discharging it;
an oxygen generator 140 provided at a rear end of the air compressor 130 and generating oxygen;
an ozone generator 150 generating ozone from the oxygen generated by the oxygen generator 140;
a mixer 160 in which water passed through the filter 120 and ozone supplied from the ozone generator 150 are mixed;
a nano-bubble generator 170 for forming nano-bubble ozone water with an increased dissolution rate of ozone by converting the water and ozone mixed in the mixer 160 into nano-bubbles;
Farmland nano-bubble ozone water supply device comprising a discharge pipe 190 for supplying the nano-bubble ozone water discharged from the nano-bubble generator 170 to farmland.
According to claim 1,
a pressure pump 180 provided between the nano bubble generator 170 and the discharge pipe 190 to increase the discharge pressure of the nano bubble ozone water;
Further comprising a plurality of distribution pipes 191 branching from the discharge pipe 190 to supply nanobubble ozone water to farmland,
The distribution pipe 191 is provided to be buried in the ground of farmland and sprays nanobubble ozone water directly toward the roots and soil of farmland.

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