KR20240020089A - Aeroponics-type plant cultivation apparatus and plant cultivation method using thereof - Google Patents

Abstract

The present invention relates to a spray-type plant cultivation device and a plant cultivation method using the same, and more specifically, to a main body ( 100); A network-shaped distribution plate 210 mounted inside the upper side of the main body 100, a communication pipe 220 in the form of a cylindrical tube extending upward from the edge of a hole formed in the distribution plate 210, and the communication pipe 220 A medium member 200 including an opening and closing member 230 that opens and closes and a culture medium 240 that covers the top of the cultivation plate 210; A cover 300 that selectively opens and closes the upper opening of the main body 100; It relates to a spray-type plant cultivation device and a plant cultivation method using the same.

Description

Spray-type plant cultivation apparatus and plant cultivation method using the same {Aeroponics-type plant cultivation apparatus and plant cultivation method using the same}

The present invention relates to a spray-type plant cultivation device for cultivating plants in a hydroponic method by spraying a nutrient solution and a plant cultivation method using the same.

Plant cultivation is largely classified into open field cultivation and hydroponic cultivation, and open field cultivation is an agricultural method that grows crops in natural farmland. And hydroponic cultivation is a method of growing plants by submerging the roots in a nutrient solution containing nutrients. Hydroponic cultivation methods are gradually spreading due to the advantages of pollution-free cultivation and maintaining freshness in response to the decrease in farmland and agricultural population due to industrial development and the trend toward four-season consumption.

Hydroponic cultivation is largely classified into solid culture (Substrate culture) and pure water culture (Water culture) depending on whether or not a culture medium is used. Solid culture media is a method of growing crops by supplying the required amount of water as a culture medium to a small amount of media that can support the crop. It is classified into inorganic media, organic media, and mixed media depending on the type of media. Pure hydroponics is a method of cultivating by exposing roots directly to the culture medium without using a medium. This includes liquid hydroponics, thin film hydroponics, and spray hydroponics.

Deep Flow Technique has the problem that the roots of crops are supplied with nutrients while always being immersed in a nutrient solution, and the roots rot due to lack of respiration, resulting in low crop growth.

Nutrient Film Technique is a cultivation method that allows a small amount of culture medium to flow through a pipe. The name was given to emphasize that the nutrient solution flowing between the roots forms a thin film-like membrane to ensure sufficient supply of oxygen to the roots.

However, in drainage devices such as thick liquid aquaponics and thin film aquariums, the flow of nutrient solution is very slow and the space between the water surface of the nutrient solution and the cultivation plate is very narrow, so ventilation is poor. As a result, in high temperature periods such as summer, the nutrient solution and the bottom of the cultivation plate are blocked. The temperature in the space rises excessively, creating good conditions for the activity of various germs, making the roots of crops susceptible to necrosis or pest damage. To prevent this, temperature control work such as installing a separate heat exchanger is required, which increases facility costs. As a result, there was a problem of worsening profitability.

In addition, because the flow of the nutrient solution on the substrate is slow, a large amount of water is retained, and a high level of support rigidity is required in the equipment to support the weight of this excessive water, so the equipment structure becomes complex and bulky, making management difficult. Furthermore, a large power device is required for the circulation of the nutrient solution, and a lot of time and manpower are consumed in the management of the nutrient solution, such as disinfection, heating, filtration, and cooling, which increases maintenance costs and reduces work efficiency.

Aeroponics is a method of spraying particulate nutrient solution toward the roots of plants exposed to the air using a spray nozzle without immersing the roots in water after germination and seedling of crops. Aeroponics uses a minimum amount of water. At the same time, it has the advantage of sufficiently supplying oxygen to the roots.

Recently, spray hydroponics grows crops on an advanced culture medium by spraying water and nutrients onto the roots that come down through the fabric. It uses about 95% less water than regular farming methods and about 40% less water than existing hydroponic cultivation methods. There are successful cases where crop yields are improved by 75% compared to existing smart farms by applying spray hydroponics and LED optimization technology.

In the 4th industrial era, there is a growing possibility that the spray hydroponic method can evolve one step further in Korea. For example, various types of hydroponic spraying methods, such as the "spray hydroponic cultivation device" of Korea Registered Patent No. 10-1477087 (Patent Document 1), are available. Cultivation methods and devices are being developed, and ideas such as “Method of increasing vitamin C content of cabbage and sprout vegetables by LED light source conditions” in Republic of Korea Patent Publication No. 10-2018-0054455 (Patent Document 2) are being developed. Because. In the future, if big data on crop cultivation is accumulated and excellent IT and 4th industrial technologies are applied, spray hydroponics will develop into an essential technology to solve water shortages and food shortages.

However, although the need for and demand for spray hydroponic systems is increasing, there is a severe shortage of cultivators that can grow crops using spray hydroponic systems, and there is a need to develop various spray hydroponic growers. The development of spray hydroponic cultivation devices solves problems by taking advantage of the advantages of spray hydroponic systems and complementing the shortcomings, but is especially effective when taking a convergence approach with IT and the 4th industrial revolution.

The important elements in a cultivation device to take advantage of spray hydroponics are the spray system and cultivation system. The spraying system must ensure independent and stable operation through the application of IT technology, and the cultivation system must have a smooth supply of water and nutrient solution sufficient for seedling and growth.

A sprayer is a device for spraying liquid such as water into fine particles. Spraying systems can be divided into high-pressure spraying, which sprays water and nutrients at high pressure, and ultrasonic spraying, which generates vibrations with ultrasonic waves to turn water into fine particles and spray them into the air. there is. Ultrasonic spraying has a vibrator to generate ultrasonic waves, and when the vibrator connected to the filter that supplies water is driven, water droplets bounce off the water surface above the vibrator, generating atomized water vapor. This atomized water vapor is supplied to the seeds to germinate them, or to the roots of crops to grow them.

The biggest problem in the spray system is that the spray nozzle is clogged and the nutrient solution is not supplied. Additionally, since the spraying system operates with electricity and PCBs, plants may be damaged in the event of a power outage or malfunction of the sprayer.

In addition, plant cultivation generally involves germination and seedling followed by transplanting, and recently, direct seeding cultivation methods have also been actively used. Direct seeding is a farming method in which crops are grown by sowing seeds without transplanting, eliminating the need for labor hours such as seedbed management or transplanting efforts. Depending on the crop, transplant cultivation can prevent growth difficulties and temporary cessation of growth due to root damage caused by transplantation. In the meantime, direct seeding cultivation was discouraged because it became difficult to protect young seedlings from pests, diseases, cold damage, and injuries that are characteristic of farmland cultivation, and it required a lot of effort to control weeds. However, in the case of hydroponic cultivation, these factors were structurally eliminated. Therefore, there is a need to actively utilize direct seeding. In particular, it goes without saying that in the case of sprout plants, there is a need to develop a cultivation system to enable direct sowing of leafy vegetables, etc.

In a spray hydroponic cultivation system that allows for everything from germination to growth through direct seeding, a cultivation system that takes into account the germination and seedling stages when roots have not yet emerged must be developed. There is no problem with the growth of crops with roots in the state if nutrient solution is supplied to the roots by spraying from under the cultivation plate, but there are problems with the supply of nutrients to crops in the germination and seedling stage when roots have not fully developed yet. There is a need to develop a device that can supply sufficient moisture, oxygen, and light during germination and seedling growth.

In addition, the advantage of spray hydroponics is that it provides sufficient oxygen to crops, allowing for efficient cultivation. By installing sufficient ventilation holes, decomposing the nutrient solution and spraying it into fine particles, the supply of nutrients and moisture to the roots of crops is smooth, ventilation is improved, root diseases caused by bacteria are minimized, and large amounts of water are stored in the minimum space. There is a need to develop devices that can grow crops.

1. Republic of Korea Patent No. 10-1477087 2. Republic of Korea Patent Publication No. 10-2018-0054455

The present invention was developed to solve the above-described conventional problems, and the purpose of the present invention is to provide a spray hydroponic cultivation device that increases the germination rate of crops through direct seeding cultivation and enables both seedling and growth.

In addition, the purpose of the present invention is to provide a spray hydroponic cultivation device with a structure in which the spray nozzle, which is the most important element in the spray hydroponic method, is not clogged.

In addition, the purpose of the present invention is to provide a spray hydroponic cultivation device that can compensate for the disadvantages of the spray hydroponic method when a power outage or sprayer failure occurs.

In addition, the purpose of the present invention is to provide a spray hydroponic cultivation device in which ventilation is smooth so that oxygen is smoothly supplied to crops.

In addition, the purpose of the present invention is to provide a spray hydroponic cultivation device in which the spray-type nutrient solution supplied to crops in the nutrient solution cultivation method can be directly circulated and used.

Furthermore, the spray hydroponic cultivation device applying the 4th industrial technology enables direct sowing of sprout plants and leafy vegetables from germination to seedling and growth, and can be used for mandatory elementary and middle school software education and experience classes, as well as for edible cultivation and nutritional intake in homes and offices. In addition, by using the designed structure and method, efficient spray hydroponic cultivation can be activated in smart farms and plant factories, and the purpose is to contribute to strengthening national competitiveness through export by commercializing the spray hydroponic cultivation system. there is.

The spray-type plant cultivation device of the present invention to achieve the above object,

A main body with an open top, a nutrient solution storage space formed inside, and a spray means to atomize the nutrient solution;

A network-shaped cultivation plate mounted inside the upper interior of the main body, a communication pipe in the form of a cylindrical tube extending upward from the edge of a hole formed in the cultivation plate, an opening and closing member for opening and closing the communication pipe, and a culture covering the upper part of the cultivation plate. Absent medium containing medium;

a cover that selectively opens and closes the upper opening of the main body; Its characteristic is that it is composed of .

In a preferred embodiment, the main body forms the nutrient solution storage space inside with the top open, and has a nutrient solution atomization unit equipped with the spray means, the top and bottom are open, respectively, and a cultivation plate of the medium member is placed on the inner peripheral surface. A mounting ledge is formed and may include a cultivation unit detachably provided at the upper part of the nutrient solution atomization unit.

In addition, a first inclined plate extending downward from the upper inner peripheral surface of the nutrient solution atomization unit toward the center and forming a first through hole at an end thereof is further provided, and/or extends downward from the lower inner peripheral peripheral surface of the cultivation unit toward the center. A second inclined plate having a second through hole formed at an end may be further provided.

At this time, the vibrator of the spray means may be disposed inclinedly by being formed on the first inclined plate.

Additionally, the cover may be provided with at least one ventilation hole or fan.

Additionally, the main body may be provided with a power storage means for applying power to the spray means.

In addition, for light-germinating seeds that require light to germinate, the cover can be made of a transparent material to allow light to pass through. Conversely, in the case of dark-germinating seeds that germinate in the dark, the cover can be used to germinate the seeds in a dark state. The cover may be made of an opaque material that blocks light transmission.

On the other hand, the plant cultivation method using the spray-type plant cultivation device of the present invention is:

After stacking the culture medium on the cultivation plate and placing seeds on the culture medium, the opening is removed to open the communication pipe, and then the top opening of the main body is closed with the cover and the spraying means is operated to form the main body. A pre-germination cultivation step of simultaneously spreading the atomized nutrient solution into the inner space of and the inner space of the cover;

After the seed is germinated, the cover is removed to open the upper opening of the main body, and then the communication pipe is closed with the opening and closing hole so that the nutrient solution atomized through the spray means is applied only to the roots exposed to the lower part of the cultivation plate. Post-cultivation stage; Its characteristic is that it includes .

According to the present invention, it is possible to provide a spray hydroponic cultivation device that increases the germination rate of crops by direct seeding cultivation and enables both seedling and growth.

In addition, it is possible to provide a spray hydroponic cultivation device with a structure in which the spray nozzle, which is the most important element in the spray hydroponic method, is not clogged.

In addition, it is possible to provide a spray hydroponic cultivation device that can be used continuously by compensating for the disadvantages of the spray hydroponic method such as power outages or sprayer failures.

In addition, it is possible to provide a spray hydroponic cultivation device in which ventilation is smooth so that oxygen is smoothly supplied to crops.

In addition, it is possible to provide a spray hydroponic cultivation device in which the sprayed nutrient solution supplied to crops in the nutrient solution cultivation method can be directly circulated and used.

In addition, the spray-type plant cultivation device of the present invention, which applies the 4th industrial technology, enables direct seeding of sprout plants and leafy vegetables from germination to seedling and growth, and can be cultivated for food in mandatory elementary and middle school software education and experience classrooms, and at home and offices. It can be used for nutritional intake, etc. In addition, efficient spray hydroponic cultivation can be activated in smart farms and plant factories by utilizing the designed structure and method, and it can contribute to strengthening national competitiveness through export by commercializing the spray hydroponic cultivation system. You can do it.

Figure 1 is a cross-sectional view showing the configuration of a spray-type plant cultivation device according to the present invention.
Figure 2 is a perspective view of a medium member in the spray-type plant cultivation device according to the present invention.
Figure 3 is a state diagram showing the cultivation stage before germination of seeds using the spray-type plant cultivation device according to the present invention.
Figure 4 is a state diagram showing the cultivation stage after germination of seeds using the spray-type plant cultivation device according to the present invention.

The present invention can be modified in various ways and can have various embodiments. Hereinafter, preferred embodiments of the present invention will be exemplified and the present invention will be described in detail. However, this is not intended to limit the present invention to only the exemplified embodiments, and the spirit and technical scope of the present invention includes common changes, equivalents, and replacements of the exemplified forms.

Additionally, the terms used in the detailed description are only used to describe specific embodiments and should not be construed as limiting the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise, and throughout the specification, when a part is 'connected' with another part, it means 'directly connected' or 'indirectly connected' with an element. Includes, and terms such as 'include' or 'have' any component are intended to designate the existence of features, numbers, steps, operations, components, parts, or a combination thereof described in the specification, but one or more of them. It should not be construed as excluding in advance the possibility of the presence or addition of other features, numbers, steps, operations, components, parts, or combinations thereof. Therefore, unless specifically stated to the contrary, it does not mean that other components are excluded, but that other components can be added.

Figure 1 is a cross-sectional view showing the configuration of a spray-type plant cultivation device according to the present invention, and Figure 2 is a perspective view of a medium member in the spray-type plant cultivation device according to the present invention.

1 and 2, the spray-type plant cultivation apparatus of the present invention includes a main body 100, a medium member 200, and a cover 300.

The main body 100 has an open top, a nutrient solution storage space 111 is formed inside, and a spray means 112 for atomizing the nutrient solution is provided at the bottom.

The spray means 112 is not limited in type or structure as long as it is a means for atomizing the nutrient solution contained in the nutrient solution storage space 111. For example, an ultrasonic vibrator or a high pressure spray nozzle applied to a humidifier may be applied.

The medium member 200 is a support structure for germinating and growing seeds in a seated state, and is mounted inside the upper side of the main body 100 and includes a net-shaped cultivation plate 210 on which the seeds are seated, and the cultivation plate ( A communication tube 220 in the form of a cylindrical tube extending upward from the edge of the hole formed in 210), an opening and closing member 230 for opening and closing the communication tube 220, and a culture medium 240 covering the upper part of the cultivation plate 210. It can be included.

In addition, the discharge member 200 may further include a fan 250 installed inside the communication pipe 220 and a wick 260 hanging down from the reprint 210.

The cultivation plate 210 may be in the shape of a disk, the communication pipe 220 may be in a shape extending upward from the center of the cultivation plate 210, and the culture medium 240 may be, for example, a foam having a through hole. It can be manufactured from synthetic resin or non-woven material.

The cover 300 is open at the bottom and has a space formed inside, and is provided to selectively open and close the top opening of the main body 100.

Below, preferred embodiments of each component of the spray-type plant cultivation device will be described.

As shown, the main body 100 may be manufactured in a separate form into a nutrient solution atomization unit 110 and a cultivation unit 120.

The nutrient solution atomization unit 110 forms the nutrient solution storage space 111 inside with the top open, and the spray means 112 is built into the nutrient solution atomization unit 110 to discharge the atomized nutrient solution through the top opening.

At this time, a control unit 113 may be installed on one side of the nutrient solution atomization unit 110 for the user to control the plant cultivation device, and power may be applied to the spray means 112 on one side of the nutrient solution atomization unit 110. A power storage member 114 may be built in, and the power storage member 114 may be a disposable battery or a rechargeable battery. In this case, the plant cultivation device can be used even in places where there is no electric outlet.

In addition, the cultivation unit 120 is open at the top and bottom, respectively, and a mounting ledge 121 for mounting the cultivation plate 210 of the medium member 200 is protrudingly formed on the inner peripheral surface, and the upper part of the nutrient solution atomization unit 110 It is provided in a detachable manner. At this time, a ventilation hole 124 through which external air enters and exits may be further provided on one side of the cultivation unit 120.

As a specific preferred embodiment, a first inclined plate 115 may be installed at the upper end of the nutrient solution atomization unit 110, and a second inclined plate 122 may be installed at the lower end of the cultivation unit 120. there is.

The first inclined plate 115 extends downward from the top of the nutrient solution atomization unit 110 toward the center to form a first through hole 116 at its end, while the second inclined plate 122 is used for the cultivation. It extends downward from the bottom of the portion 120 toward the center to form a second through hole 123 at its end. At this time, the vibrator 112a of the spray means 112 may be disposed inclinedly by being formed on the first inclined plate 115.

With this configuration, when the atomized nutrient solution falls as condensation in the internal space of the cultivation unit 120, it flows down the first inclined plate 115 and/or the second inclined plate 122 to form the nutrient solution storage space 111. Because it collects water, it can perform the function of circulating the nutrient solution. Additionally, as the vibrator (112a) is disposed at an angle, the nutrient solution flows down rather than pooling, so contamination of the vibrator (112a) can be minimized and the atomization function is prevented from being deteriorated. can do.

The fan 250 installed in the communication pipe 220 of the media member 200 can be operated as needed and is provided to forcibly move the atomized nutrient solution inside the main body 100 into the cover 300.

In addition, the wick 260 provided on the cultivation plate 210 of the medium member 200 uses capillary action to suck the nutrient solution contained in the nutrient solution storage space 111 of the main body 100 into the culture medium 240. It performs a supply function.

On the other hand, since there are light-germinating seeds that require light for seed germination and dark-germinating seeds that germinate in the dark, taking this into consideration and in order to germinate the seeds in a dark state, the cover 300 is opaque to block light without transmitting it. It can be made of a material or a transparent material so that light can pass through.

Additionally, at least one ventilation hole 310 may be formed on one side of the cover 300 to allow the introduction of external air.

Hereinafter, the state of use of the spray-type plant cultivation device of the present invention will be described with reference to FIGS. 3 and 4, through which the present invention will be further clarified.

Figure 3 is a state diagram showing the cultivation stage before germination of seeds using the spray-type plant cultivation device according to the present invention.

As shown in FIG. 3, the culture medium 240 is stacked on the cultivation plate 210, the plant seeds are placed on the culture medium 240, and the opening/closing port 230 is removed to open the communication pipe 220. The discharge member 200 is mounted on the upper part of the main body 200.

Thereafter, in the case of dark germinated seeds, the upper opening of the main body 100 is covered with a cover 300 of an opaque material in order to germinate in a dark state without light, and on the contrary, in the case of light germinated seeds, a cover of a transparent material that transmits light ( When the spray means 112 is operated while the upper opening of the main body 100 is covered with 300), the atomized nutrient solution is spread into the internal space of the main body 100, and some of the atomized nutrient solution is spread into the cover 300 through the communication pipe 220. After spreading into the internal space, it is supplied to the upper part of the culture media (200). At this time, the fan 250 provided inside the communication pipe 220 may be operated to supply more atomized nutrient solution to the inner space of the cover 300.

In this case, the atomized nutrient solution is supplied to the lower part of the seed through the cultivation plate 210 and the culture medium 240, and at the same time, the nutrient solution that has moved to the inner space of the cover 300 through the communication pipe 220 is supplied to the upper part of the seed. It is possible to increase germination efficiency and at the same time shorten the germination period. Moreover, when the wick 260 is installed, the nutrient solution can not only be supplied to the culture medium 240 through the wick 260, but also continuously through the wick 260 even if a power failure or a failure of the spray means 112 occurs. Nutrient solution can be supplied.

Figure 4 is a state diagram showing the cultivation stage after germination of seeds using the spray-type plant cultivation device according to the present invention.

Referring to FIG. 4, when germination of the seed is achieved, the cover 300 is removed from the main body 100 to open the top of the main body 100 to allow light to enter the germinated seed, and at the same time, the opening 230 is opened. By closing the communication pipe 220 to block the atomized nutrient solution from moving upward through the communication pipe 220, the atomized nutrient solution is supplied only to the roots of the plants exposed to the lower part of the cultivation plate 210.

In this case, the nutrient solution is prevented from being supplied to the plant's leaves and the nutrient solution is supplied only to the plant roots, so hydroponic cultivation is possible while minimizing the consumption of the nutrient solution, and sufficient light and oxygen are supplied to the plant leaves, making it effective for plant development.

In this way, the above description has been explained according to limited embodiments showing the technical idea of the present invention, but the present invention is not limited to specific embodiments, shapes, and values, and some of the components of the embodiments may be changed, mixed, etc. Various modifications and variations can be made by those skilled in the art without departing from the gist of the invention, and such modifications and variations should not be understood individually from the technical idea or outlook of the present invention. It will be.

100... Main body 110... Nutrient solution atomization unit
111... Nutrient solution storage space 112... Spray means
113...control unit 114...electric storage member
115... first inclined plate 116... first through hole
120... Rearrangement unit 121... Holding jaw
122... second inclined plate 123... second through hole
124... vent
200... absence of medium 210... redistribution
220... flue pipe 230... opening/closing member
240... culture medium 250... fan
260... wick
300... cover 310... vent

Claims (9)

A main body with an open top, a nutrient solution storage space formed inside, and a spray means to atomize the nutrient solution;
A network-shaped cultivation plate mounted inside the upper interior of the main body, a communication pipe in the form of a cylindrical tube extending upward from the edge of a hole formed in the cultivation plate, an opening and closing member for opening and closing the communication pipe, and a culture covering the upper part of the cultivation plate. Absent medium containing medium;
a cover that selectively opens and closes the upper opening of the main body; A spray-type plant cultivation device, characterized in that it consists of. In claim 1,
The main body forms the nutrient solution storage space inside with the top open, and includes a nutrient solution atomization unit equipped with the spray means,
A spray-type plant cultivation device characterized in that the upper and lower ends are open, a mounting ledge for holding a cultivation plate of the medium member is formed on the inner circumferential surface, and a cultivation section is provided detachably from the upper part of the nutrient solution atomization section. In claim 2,
A first inclined plate extending downward from the top of the nutrient solution atomization unit toward the center and forming a first through hole at an end thereof is further provided, or
A spray-type plant cultivation device, characterized in that it is further provided with a second inclined plate extending downward from the bottom of the cultivation unit toward the center and forming a second through hole at an end thereof. In claim 3,
A spray-type plant cultivation device, characterized in that the vibrator of the spray means is formed on the first inclined plate and is thus disposed inclinedly. In claim 1,
A spray-type plant cultivation device, characterized in that the inside of the communication pipe is further provided with a fan for moving the atomized nutrient solution into the inside of the cover. In claim 1,
A spray-type plant cultivation device, characterized in that the cultivation plate is further provided with a wick for sucking up the nutrient solution contained in the nutrient solution storage space and supplying it to the culture medium. In claim 1,
A spray-type plant cultivation device, characterized in that at least one ventilation hole is provided on one side of the main body or cover. In claim 1,
The cover is made of a transparent material that allows light to pass through or an opaque material that blocks the passage of light, so that it can be selected depending on the germination conditions of the seed. A plant cultivation method using the spray-type plant cultivation device according to any one of claims 1 to 8,
After stacking the culture medium on the cultivation plate and placing seeds on the culture medium, the opening is removed to open the communication pipe, and then the top opening of the main body is closed with the cover and the spraying means is operated to form the main body. A pre-germination cultivation step of simultaneously supplying atomized nutrient solution to the inner space of and the inner space of the cover;
After the seed is germinated, the cover is removed to open the upper opening of the main body, and then the communication pipe is closed with the opening and closing hole so that the nutrient solution atomized through the spray means is applied only to the roots exposed to the lower part of the cultivation plate. Post-cultivation stage; A plant cultivation method comprising: