KR20210131711A - Plant cultivation system including floor type nutrient solution tank - Google Patents

Abstract

The present disclosure relates to a plant cultivation system including a floor type nutrient solution storage tank, and more specifically, to a plant cultivation system including a floor type nutrient solution storage tank capable of increasing the efficiency of nutrient solution recovery through the nutrient solution storage tank formed on the floor without forming a separate nutrient solution storage tank. The plant cultivation system according to one embodiment of the present disclosure includes: a layer division support frame including a plurality of horizontal frames and vertical frames so that a planting bed for plant cultivation is installed while being divided into a plurality of cultivation layers; a plurality of cultivation tables extending in the longitudinal direction from the plurality of cultivation layers, and spaced apart from each other by a predetermined distance in the width direction of the cultivation layers, wherein the planting bed for plant cultivation is installed on the cultivation tables; a nutrient solution supply unit connected to one side of the cultivation tables and supplying a nutrient solution delivered from a nutrient solution circulation system; a nutrient solution flowing unit installed at the lower part of the cultivation tables and allowing the nutrient solution supplied from the nutrient solution supply unit to flow to the lower part of the planting bed to supply the nutrient solution to plants; a nutrient solution recovery unit connected to the other side of the cultivation tables to recover the nutrient solution discharged from the nutrient solution flowing unit; and a drainage storage tank installed at the lower part of the layer division support frame and including an access floor spaced apart from the ground by a predetermined distance, a trench unit installed through the access floor, and a kernel unit formed therein with a predetermined space to store the nutrient solution recovered from the nutrient solution recovery unit to the trench unit.

Description

Plant cultivation system including floor type nutrient solution tank

The present disclosure relates to a plant cultivation system including a bottom-type nutrient solution storage tank, and more particularly, it is possible to increase the efficiency of nutrient solution recovery through a nutrient solution storage tank formed on the floor without separately configuring a separate nutrient solution storage tank for drainage. It relates to a plant cultivation system including a bottom-type nutrient solution storage tank.

Unless otherwise indicated herein, the material described in this section is not prior art to the claims of this application, and inclusion in this section is not an admission that it is prior art.

The artificial light plant factory started in 1957 in Europe, where plants were cultivated using supplementary light, and then developed into a fully controlled plant factory using only artificial light in the United States in the 1960s. As they put salad vegetables on the market, they were able to secure the related technologies to date.

In the artificial light plant factory where plants are artificially grown as described above, an artificial cultivation bed is used instead of a large land such as a vegetable garden. The above cultivation table can be used for various purposes, and the purpose of multi-level cultivation is the biggest, and with the recent development of many technologies, the concept of multi-level cultivation simply stacked up in multiple layers is further developed, and even a movable plant cultivation table has been developed. come.

The nutrient solution supplied to the plants planted in such a plant growing table is a nutrient solution formulated with the nutrients necessary for plant cultivation according to the characteristics of the plant, and is configured to be continuously supplied during the anniversary production. Fertilizer components of the nutrient solution are divided into a large amount of essential elements and trace amounts of essential elements, and when 80 to 90% of the weight of the plants grown in the artificial light plant factory is water (H ₂ O), and the remainder is 100, carbon ( C) and oxygen (O) are each 45%, and hydrogen (H) is composed of about 6%. They are absorbed into the plant during photosynthesis, and macroelements and trace elements are absorbed from the roots in the form of ions. The elements absorbed from the roots move into the plant body, and energy is required for selective absorption, and this energy is obtained through root respiration.

Plants grown in the plant factory have a faster growth rate than open-field cultivation, so the consumption of nutrient solution increases, and an ion imbalance in the supply nutrient solution affects growth. It is also possible to prevent sudden changes in the formulated nutrient solution or to correct the nutrient solution concentration while continuously monitoring the status of the nutrient solution. In such nutrient solution management, if the temperature of the nutrient solution increases, the respiration rate of the roots increases and the amount of dissolved oxygen decreases, resulting in a lack of oxygen.

In general, the nutrient solution supply system is composed of a raw water tank, a liquid fertilizer tank, a mixing tank, various sensors and valves/filters, a concentrated nutrient solution supply device including a pump, a drainage tank, a UV sterilizer, a nutrient solution control system, and the like. In the case of a multi-stage plant culture table to which the system is applied, beds for plant cultivation are arranged in a line to form one culture bed, and the culture bed forms a plurality of layers to form one multi-stage culture bed. In order to mount such a multi-stage culture table, a rack for supporting each culture bed is provided, a nutrient solution flows to each culture bed, and a waterway is formed to mount the crops. In addition, a recovery pipe for delivering the nutrient solution recovered from the plants and a drainage tank for storing the recovered nutrient solution are formed in the lower part of the multi-stage culture table. In the case of a small plant factory, a small-sized storage tank is installed at the bottom of the multi-stage bed. shall.

This is not a problem when the number of the multi-stage culture beds is small, but as the size of the culture bed increases or the number of the multi-stage culture beds increases, the amount of nutrient solution to be circulated increases in proportion, so that a separate nutrient solution storage (or drainage) ) There is a problem in that production is reduced due to the reduction of the cultivation bed because it is necessary to install a tank or empty the cultivation bed installed in the lower part of the multi-level culture bed and install a nutrient solution storage tank.

In addition, if the number of cultivation beds itself increases, a nutrient solution storage tank must be buried and installed in the basement of the area where the multi-level culture table is installed in order to supply the nutrient solution to a large number of cultivation tables. However, it affects the underground environment, and there is a disadvantage that a separate system must be provided to manage it as a whole. In particular, the increase in plant factory construction costs is a factor that hinders industrial development. In addition, if the nutrient solution recovery tank is installed outside the closed plant factory building, it not only provides an excuse for an increase in pollution sources, but also increases the temperature of the drainage. Exposure to room temperature contains several problems, such as an increase in the respiration rate from the roots. In addition, in the case of a plant factory, since a multi-level cultivation table is installed inside the building, it is impossible to excavate the nutrient solution storage tank on the floor, so there is a limitation in the installation area that must be installed on the first floor or basement of the building.

1. Korean Patent Registration No. 10-1953620 (2019.03.04 Announcement) 2. Korean Patent Registration No. 10-1423127 (Announcement on July 25, 2014) 3. Korean Patent Registration No. 10-0869813 (published on November 26, 2008)

Regardless of the size of the plant factory, it is intended to provide a plant cultivation system that can increase the efficiency of nutrient solution recovery through a nutrient solution storage tank formed on the floor of the same cultivation room without configuring a separate nutrient solution storage (drainage) tank.

In addition, it is not limited to the technical problems as described above, and it is obvious that another technical problem may be derived from the following description.

A plant cultivation system according to an embodiment of the present disclosure includes a layer division support frame formed of a plurality of horizontal frames and vertical frames so that a planting bed for plant cultivation is partitioned into a plurality of cultivation layers and installed, and in the plurality of cultivation layers It is installed extending in the longitudinal direction, a plurality of the cultivation beds are spaced apart from each other by a predetermined distance in the width direction, and a plurality of cultivation tables on which the planting beds for plant cultivation are installed are connected to one side of the cultivation bed, and are separated from the nutrient solution circulation system. A nutrient solution supply unit for supplying the delivered nutrient solution, a nutrient solution flow unit installed at the lower part of the cultivation table, the nutrient solution flow unit for supplying the nutrient solution to the plants by flowing the nutrient solution supplied from the nutrient solution supply unit to the lower part of the planting bed, and the other side of the cultivation table is connected a nutrient solution recovery unit for recovering the nutrient solution discharged from the nutrient solution flow unit; A predetermined space is formed therein and includes a drainage reservoir including a kernel part for storing the nutrient solution recovered from the nutrient solution recovery part to the trench part.

According to a preferred feature of the present disclosure, the nutrient solution recovery unit interconnects the nutrient solution storage unit for storing the nutrient solution delivered from a plurality of nutrient solution flow units installed in each cultivation layer and the nutrient solution storage unit of each cultivation layer, and the stored nutrient solution It is characterized in that it comprises a nutrient solution recovery pipe for supplying to the trench portion.

According to a preferred feature of the present disclosure, a plurality of the layer partition support frames are arranged to be spaced apart by a predetermined distance, and a moving means is installed at a lower portion of each support frame, and a plurality of moving parts are installed extending along the width direction of the cultivation layer. It is characterized in that it moves in conjunction with the rail.

According to a preferred feature of the present disclosure, the trench portion is installed to extend along the width direction of the cultivation layer, and when the layer partition support frame moves, the nutrient solution recovery pipe is moved along the length direction of the trench portion.

According to a preferred feature of the present disclosure, it communicates with the trench portion, it is characterized in that it further comprises a kernel portion forming a predetermined space to store the recovered nutrient solution and re-supply to the nutrient solution circulation system.

According to a preferred feature of the present disclosure, it is installed between the trench portion and the kernel portion, characterized in that it further comprises a perforated plate through which the nutrient solution flows through the perforated hole.

According to a preferred feature of the present disclosure, the trench portion and the kernel portion are characterized in that the structure is inclined at a predetermined angle from the ground.

According to a preferred feature of the present disclosure, it is installed at a predetermined height on one side of the kernel part, it characterized in that it further comprises a nutrient solution discharge device for re-supplying the nutrient solution recovered to the kernel part to the nutrient solution circulation system.

According to an embodiment of the present disclosure, there is an advantage of storing and circulating the nutrient solution without having a separate nutrient solution storage tank in the lowermost layer of the plant growing table or excavating underground.

By installing the nutrient solution recovery tank indoors, it is possible to reduce the penetration of pollutants of the nutrient solution and to keep the drainage temperature the same as the environment in the cultivation room, thereby saving energy and helping roots respiration by maintaining an appropriate temperature (21℃). It has the advantage of being able to give.

In addition, according to an embodiment of the present disclosure, there is an advantage in that an additional plant cultivation space is secured by not installing a nutrient solution storage tank, and thus the production is increased.

It should be understood that the effects of the present invention are not limited to the above-described effects, and include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a perspective view of a plant cultivation system according to an embodiment of the present disclosure;
2 is a side view of a plant cultivation system according to an embodiment of the present disclosure;
3 is a detailed view of a trench portion and a kernel portion in a plant cultivation system according to an embodiment of the present disclosure;
4 is a state diagram in which a plurality of plant cultivation tables are installed in the plant cultivation system according to an embodiment of the present disclosure;
5 is a conceptual diagram showing the entire system of a plant cultivation system according to an embodiment of the present disclosure.

Hereinafter, the configuration, operation, and effect of the plant cultivation system according to a preferred embodiment will be described with reference to the accompanying drawings. For reference, in the following drawings, each component is omitted or schematically illustrated for convenience and clarity, and the size of each component does not reflect the actual size. In addition, the same reference numerals refer to the same components throughout the specification, and reference numerals for the same components in individual drawings will be omitted.

1 shows a perspective view of a plant cultivation system according to an embodiment of the present disclosure, and FIG. 2 shows a side view.

The plant cultivation system according to an embodiment of the present disclosure supports a layer division formed of a plurality of horizontal frames 11 and vertical frames 13 so that the planting bed 21 for plant cultivation is partitioned into a plurality of cultivation layers and installed. A plurality of cultivars in which the frame 10 and the plurality of cultivation layers are installed extending in the longitudinal direction, spaced apart from each other by a predetermined distance in the width direction of the cultivation layers, and a plurality of the planting beds 21 for plant cultivation are installed. The nutrient solution supply unit 30 is connected to the stand 20, one side of the cultivation table 20 and supplies the nutrient solution delivered from the nutrient solution circulation system, and is installed under the cultivation table 20, and the nutrient solution supply unit The nutrient solution flowing part 40 for supplying the nutrient solution to the plants by flowing the nutrient solution supplied from 30 to the lower part of the planting bed 21, and connected to the other side of the cultivation table 20, the nutrient solution flow part 40 ) and a nutrient solution recovery unit 50 for recovering the nutrient solution discharged from the access floor 60 and the access floor 60 installed at the lower part of the floor partition support frame 10 and spaced apart from the ground by a predetermined distance. Drainage storage tank (2) including a trench part 70 installed through the ) is included.

First, the layer partition support frame 10 is made of one layer by a horizontal frame 11 consisting of a longitudinal frame extending to one side and a width direction frame extending in the width direction. A plurality of planting beds 21 may be installed between the horizontal frames 11, which will be described later. Next, the horizontal frame 11 includes a vertical frame 13 configured to be arranged in a plurality of spaced apart in a vertical direction. The floor partition support frame 10 composed of the horizontal frame 11 and the vertical frame 13 is installed on the upper part of the access floor 60, and the floor partition support frame 10 is provided in a plurality of pieces depending on the installation area. may be installed.

A plurality of cultivation tables 20 installed extending in the longitudinal direction from the plurality of cultivation layers, spaced apart from each other by a predetermined distance in the width direction of the cultivation layers, and on which the planting beds 21 for plant cultivation are installed, are further provided. may include

It is installed in a plurality of cultivation layers partitioned by each horizontal frame 11 of the layer division support frame 10, and the planting bed 21 for plant cultivation is made such that one or more plants are planted in a line along the longitudinal direction of the bed. It is installed extending along the longitudinal direction so that the planting bed 21 can be installed. In addition, a plurality of cultivation tables 20 may be arranged side by side in the width direction according to the length of the frame in the width direction of the layer partition support frame 10 . Here, the planting bed 21 has a planting hole formed through the upper side to enable planting of the plant, and the nutrient solution can be supplied to the plant through a space through which the nutrient solution can flow therein.

In addition, it further includes a nutrient solution supply unit 30 connected to one side of the cultivation table 20 and supplying the nutrient solution delivered from the nutrient solution circulation system. The nutrient solution supply unit 30 is configured to supply the nutrient solution from the nutrient solution circulation system to the planting bed 21, and the nutrient solution pumped to the upper portion of the layer compartment support frame 10 through a pump or the like extends in the vertical direction. It is configured to be supplied to the cultivation tables 20 installed on each floor through one or more nutrient solution supply pipes 31 that ) is divided into a plurality of tubes so that they can be supplied to each cultivation table 20 . A valve or the like is installed in each pipe of the nutrient solution supply unit 30 to control the amount and speed of the supplied nutrient solution, and in particular, it is possible to control a large amount of nutrient solution to be supplied to the culture table 20 required for the nutrient solution.

In addition, it is installed in the lower part of the cultivation table 20, and flows the nutrient solution supplied from the nutrient solution supply unit 30 to the lower part of the planting bed 21 to supply the nutrient solution to the plants. can do. The nutrient solution is supplied from the nutrient solution supply unit 30 to the cultivation table 20, where it is installed at the bottom of the cultivation table 20 and through the nutrient solution flow unit 40 forming a space through which the nutrient solution can flow, the cultivation table ( 20), it will be possible to supply the nutrient solution to the planted plants. The nutrient solution flow unit 40 is coupled to the lower portion of the cultivation table 20 and has an open top and a curved shape toward the inside, so that the nutrient solution flows smoothly and quickly.

Next, it further includes a nutrient solution recovery unit 50 connected to the other side of the cultivation table 20 to recover the nutrient solution discharged from the nutrient solution flow unit 40 . The nutrient solution recovery unit 50 is installed on the other side of the cultivation table 20, more specifically, under the cultivation table 20, is connected to the nutrient solution flow unit 40 through which the nutrient solution flows, and collects and recovers the nutrient solution. Here, the nutrient solution recovery unit 50 is installed at the lower portion of the nutrient solution flow unit 40, and the flowing nutrient solution is naturally discharged to the bottom and collected by the nutrient solution recovery unit 50, preferably the cultivation table 20 ) may be installed extending along the width direction to collect and recover the nutrient solution discharged from the plurality of cultivation tables 20 .

According to a preferred feature of the present disclosure, the nutrient solution recovery unit 50 includes a nutrient solution storage unit 51 for storing the nutrient solution delivered from a plurality of nutrient solution flow units 40 installed in each cultivation table 20 and It is characterized in that it interconnects the nutrient solution storage unit 51 of each cultivation table 20 and includes a nutrient solution recovery pipe 53 for supplying the stored nutrient solution to the trench unit 70 .

In the nutrient solution recovery unit 50, the nutrient solution flow unit 40 ) may form a nutrient solution storage unit 51 forming a predetermined space in order to partially store the nutrient solution delivered from. In addition, one or more nutrient solution storage units 51 may be installed in each cultivation layer, and the nutrient solution storage units 51 installed in each cultivation layer are interconnected to supply the stored nutrient solution to the trench unit 70 . The nutrient solution can be discharged by the recovery pipe 53 .

3 shows a detailed view of a trench portion and a kernel portion in a plant growing table according to an embodiment of the present disclosure.

It is installed under the floor partition support frame 10 and is installed through the access floor 60 and the access floor 60 installed to be spaced apart from the ground by a predetermined distance, and a predetermined space is formed therein to recover the nutrient solution. and a trench part 60 for storing the nutrient solution recovered from the part 50 and re-supplying it to the nutrient solution circulation system.

The access floor 60 is spaced apart from the ground by a predetermined distance to form another floor, and a gap of about 20 to 40 cm may be formed between the ground and the access floor 60, and nutrient solution can be stored between the spaces. A nutrient solution reservoir can be installed. In more detail, the floor partition support frame 10 is installed at a position spaced a predetermined distance from the ground by the access floor 60, and the nutrient solution is drained from the nutrient solution recovery unit 50 by the flow system of the nutrient solution. It is transferred to (2), and the drainage water tank 2 is installed under the access floor 60 and is configured to store the recovered nutrient solution and re-supply it to the nutrient solution circulation system when it is stored above a certain level. The trench portion 70 of the drainage tank 2 may be formed in a hexahedral shape having a predetermined volume under the access floor 60, and has a height extending from the ground to the lower surface of the access floor 60, and the cultivation layer It is preferably made of a rectangular parallelepiped extending along the width direction of the .

According to a preferred feature of the present disclosure, it communicates with the trench part 70, and further comprises a kernel part 80 forming a predetermined space to store the recovered nutrient solution and re-supply it to the nutrient solution circulation system. do it with

The kernel unit 80 is configured to store and supply the nutrient solution to the nutrient solution circulation system as the amount of nutrient solution transferred from the nutrient solution recovery pipe 53 to the trench section 70 increases, and communicates with the trench section 70 Nutrient solution may be delivered, and may have a larger volume than the trench portion 70 . For example, the kernel part 80 is configured to communicate with the trench part 70 from the lower part of the access floor 60 , and is formed to extend in the central direction of the layer partition support frame 10 to have a larger volume. may have a shape. Accordingly, the nutrient solution flowing through the trench part 70 may move to the kernel part 80 and the nutrient solution may be stored. After that, when a predetermined amount or more is stored, the nutrient solution circulation system through the nutrient solution discharge device 81 to be described later. will be transmitted to

According to a preferred feature of the present disclosure, a plurality of the layer partition support frames 10 are arranged spaced apart by a predetermined distance, and a moving means 15 is installed at the lower portion of each support frame 10 , and the width of the cultivation layer It is characterized in that it moves in conjunction with a plurality of moving rails 63 that are installed extending along the direction.

As one layer partition support frame 10 is installed, it is possible to build a system that can supply a nutrient solution to a plurality of plants, but a plurality of these layer partition support frames 10 are installed and spaced apart at regular intervals to uniformly arrange them. When the nutrient solution can be supplied to more plants, the moving means 15 may be installed at the lower portion of each support frame 10 in order to give mobility. The moving means 15 may be made of wheels, etc., and the wheels are movable in conjunction with a plurality of moving rails 63 installed extending along the width direction of the cultivation layer from the upper surface of the access floor 60 . . Accordingly, the plurality of layer division support frames 10 are moved along the width direction of the cultivation layer based on the moving rails 63 , and accordingly, the nutrient solution recovery pipe 53 installed in each support frame 10 is also a trench. It is made to be movable along the part (70).

According to a preferred feature of the present disclosure, the trench portion 70 is installed to extend along the width direction of the cultivation layer, and when the layer partition support frame 10 moves, the nutrient solution recovery pipe 53 is connected to the trench portion 70 ) is characterized in that it moves along the longitudinal direction. In the overall system composed of a plurality of floor division support frames 10 , the trench portion 70 is not a simple open hole structure but a structure that extends long along the longitudinal direction, and is moved by the wheels of the support frame 10 . Accordingly, the nutrient solution recovery pipe 53 also moves.

According to a preferred feature of the present disclosure, it is installed between the trench portion 70 and the kernel portion 80, characterized in that it further comprises a perforated plate 90 through which the nutrient solution flows through the perforated hole.

The perforated plate 90 has a predetermined thickness and is configured to partition the spaces between the trench portion 70 and the kernel portion 80, and a plurality of holes having a predetermined diameter are formed on the surface of the perforated plate 90. It may be made to be perforated. The nutrient solution recovered to the trench part 70 moves to the kernel part 80 through a plurality of holes formed in the perforated plate 90 , and then the nutrient solution stored in the kernel part 80 is discharged through the nutrient solution discharge device 81 . It is delivered to the nutrient circulatory system.

According to a preferred feature of the present disclosure, the trench portion 70 and the kernel portion 80 are formed in a structure inclined at a predetermined angle from the ground.

The trench part 70 and the kernel part 80 may have a rectangular parallelepiped shape forming a predetermined space therein as described above, and the nutrient solution may be stored in the internal space. In order to more easily supply, the trench portion 70 and the kernel portion 80 may have a minute inclination angle. The inclination angle may form an inclination of about 0.1 to 0.5% (5/1000) from the ground, and accordingly, the nutrient solution naturally moves in the inclined direction.

According to a preferred feature of the present disclosure, a nutrient solution discharging device 81 installed at a predetermined height on one side of the kernel part 80 and for re-supplying the nutrient solution recovered in the kernel part 80 to the nutrient solution circulation system. It is characterized in that it further comprises.

The nutrient solution discharging device 81 is preferably formed on the lower side of the inclined surface, and while the nutrient solution is stored in the kernel part 80, the amount is increased while being transferred to one side by the inclination angle. Accordingly, when the water level rises above a certain level, the nutrient solution is discharged to the nutrient solution circulation system through the nutrient solution discharge device 81 formed on the side of the kernel part 80 .

By the plant plant cultivation system having the above structure, the access floor 60 and the trench part 70 and the kernel part installed under the access floor 60 without installing a separate nutrient solution storage tank on the lowest floor or excavating a nutrient solution storage tank on the floor By (80), it is possible to easily store the nutrient solution and enable the overall circulation.

Although preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and represent all of the technical spirit of the present invention. Therefore, it should be understood that there may be various equivalents and modifications that can be substituted for them at the time of filing the present application. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and their All changes or modifications derived from the concept of equivalents should be construed as being included in the scope of the present invention.

1: Plant growing table
2: Drainage tank
10: floor division support frame
11: horizontal frame
13: vertical frame
15: means of transportation
20: cultivation bed
21: planting bed
30: nutrient solution supply unit
31: Nutrient solution supply pipe
40: nutrient solution flow part
50: nutrient solution recovery unit
51: nutrient solution storage unit
53: nutrient solution recovery pipe
60: access floor
61: moving rail
70: trench part
80: kernel part
81: nutrient solution discharge device
90: perforated plate

Claims (8)

a layer partition support frame formed of a plurality of horizontal frames and vertical frames so that the planting bed for plant cultivation is partitioned into a plurality of growing layers and installed;
a plurality of cultivation tables extending in the longitudinal direction from the plurality of cultivation layers, the plurality of cultivation beds being spaced apart from each other by a predetermined distance in the width direction of the cultivation layers, and on which the planting beds for plant cultivation are installed;
a nutrient solution supply unit connected to one side of the culture bed and supplying the nutrient solution delivered from the nutrient solution circulation system;
a nutrient solution flow unit installed at the lower part of the cultivation table and configured to supply the nutrient solution to the plants by flowing the nutrient solution supplied from the nutrient solution supply unit to the lower part of the planting bed;
a nutrient solution recovery unit connected to the other side of the culture bed to recover the nutrient solution discharged from the nutrient solution flow unit;
an access floor installed under the floor partition support frame and spaced apart from the ground by a predetermined distance; and
a drainage tank including a trench part installed through the access floor and a kernel part having a predetermined space therein to store the nutrient solution recovered from the nutrient solution recovery part to the trench part;
A plant cultivation system comprising a. According to claim 1,
The nutrient solution recovery unit,
a nutrient solution storage unit for storing the nutrient solution delivered from a plurality of nutrient solution flow units installed in each cultivation layer; and
A plant cultivation system comprising a nutrient solution recovery pipe for interconnecting the nutrient solution storage units of each cultivation layer and supplying the stored nutrient solution to the trench unit. According to claim 1,
A plurality of the floor partition support frames are spaced apart from each other by a predetermined distance, and a moving means is installed at the lower portion of each support frame,
A plant cultivation system, characterized in that it moves in conjunction with a plurality of moving rails installed extending along the width direction of the cultivation layer. 4. The method of claim 3,
The trench part is installed to extend along the width direction of the cultivation layer, and when the layer division support frame moves, the nutrient solution recovery pipe is moved along the length direction of the trench part. According to claim 1,
The plant cultivation system according to claim 1, further comprising a kernel part communicating with the trench part and forming a predetermined space for storing the recovered nutrient solution and re-supplying it to the nutrient solution circulation system. 6. The method of claim 5,
It is installed between the trench portion and the kernel portion, plant cultivation system, characterized in that it further comprises a perforated plate through which the nutrient solution flows through the perforated hole. 7. The method of claim 6,
The trench part and the kernel part plant cultivation system, characterized in that made of a structure inclined at a predetermined angle from the ground. 8. The method of claim 7,
It is installed at a predetermined height on one side of the kernel part,
Plant cultivation system, characterized in that it further comprises a nutrient solution discharging device for re-supplying the nutrient solution recovered from the kernel unit to the nutrient solution circulation system.

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