KR20050016735A - hydroponic device - Google Patents

Abstract

PURPOSE: A laminate-type hydroponic device capable of optionally controlling the step number of a hydroponic pot according to the height of hydroponic facilities is provided. It enables easy observation of the course of crop growth and efficient utilization of space in hydroponic facilities. CONSTITUTION: The hydroponic device(100) consists of: a pot moving means for moving a hydroponic pot(1) containing culture soil periodically on a predetermined path; a spray nozzle for supplying nutritious liquid to the hydroponic pot from the upper part; a nutritious liquid recovery channel for recovering nutritious liquid discharged from the hydroponic pot; a interval control means. The pot moving means is a chain conveyor attached with a plurality of hydroponic pots at regular intervals. The interval control means contains at least one rail, at least one roller member(42) and a driving device for providing a driving force of the rail direction.

Description

Hydroponic device

The present invention relates to a nutrient cultivation device and a stacked nutrient solution cultivation port used in the nutrient solution cultivation device.

Nutrient cultivation method refers to a method of cultivating a crop using an aqueous solution (hereinafter, "nutrient solution") in which the essential elements required for the growth of the crop are dissolved at an appropriate concentration according to the absorption ratio. Nutrient cultivation is a scientific farming technique that can optimize the growth conditions of crops by keeping the environment uniform because it can artificially and precisely control the medium conditions of nutrient solution and root part.

Nutrient cultivation is divided into plow cultivation, hydroponic cultivation and solid medium cultivation depending on the type of excretion. Among them, the most widely used solid media cultivation currently supports crops with solid media (hereafter referred to as "cultivation soils") made of sand, perlite, rock wool, gravel, rice husk, hultan, etc. Cultivation method to supply nutrient solution.

Conventional solid medium cultivation equipment is described in the Republic of Korea Patent Application No. 1992-13535, budgeting equipment by forming a nutrient solution port on the nutrient solution cultivation bed installed on the pit in the greenhouse and each nutrient solution irrigation equipment installed for each nutrient solution port This is an overly demanding drawback. On the other hand, as another example of the prior art, Korean Patent Application No. 2000-20483 discloses a domestic nutrient cultivation device for raising crops by placing the inner container inside the styrofoam material outer container formed with a lattice drip hole to put soil in place of the culture soil Korean Utility Model Registration Application No. 2001-22173 discloses a technique for spraying nutrient solution with a nozzle installed at an upper portion of a port installed on a nutrient solution cultivation bed. However, the nutrient solution cultivation apparatus of the prior art has a problem that the nutrient solution sprinkling pipe should be installed at an appropriate position for each nutrient solution port.

In addition, the conventional nutrient cultivation apparatus can not arbitrarily adjust the height of the nutrient solution cultivation port according to the characteristics of the crop in the facility house lacking space or space, and also does not uniformly adjust the amount of sunshine due to the ceiling in the facility house.

In addition, since the nutrient solution supplied to the conventional nutrient solution cultivation port is made for each port, there is a problem in that water supply and recovery are cumbersome.

The present invention has been made to solve the above problems of the prior art, the installation cost is relatively low, nutrient solution cultivation device that can cultivate crops with high density even in a narrow space and the efficiency of water supply and recovery of nutrient solution is significantly improved And to provide a nutrient solution cultivation port for that purpose.

Nutrient cultivation port of the present invention for achieving the above object is made by stacking a plurality of nutrient solution cultivation port having a culture soil supporting the crop. The nutrient solution cultivation port has a cylindrical shape with the top and bottom open, the bottom opening for supporting the culture soil is installed in the lower opening of the nutrient solution cultivation port, at least one crop growth zone is formed on the side of the nutrient solution cultivation port do. The nutrient solution supplied from the top of the stacked nutrient solution cultivation port is configured to pass from the top nutrient solution cultivation port to the bottom nutrient solution cultivation port.

The nutrient solution cultivation port has an upper jaw and a lower jaw at its upper and lower portions, respectively, and when the plurality of nutrient solution cultivation ports are stacked, it is preferable that the lower jaw of the upper nutrient solution material port is engaged with the upper jaw of the lower nutrient solution material port.

In addition, the upper cover is installed on the upper portion of the nutrient solution cultivation port located at the top of the laminated nutrient solution cultivation port and the lower cover is installed at the bottom of the nutrient solution cultivation port located at the bottom, the upper and lower covers, respectively, from the top to the bottom It is desirable to have a funnel shape whose cross sectional area gradually decreases.

In addition, the plurality of nutrient solution cultivation port and the upper portion of the upper and lower cover through the hole through which the rope is inserted, respectively, the hook is formed on the upper end of the rope, it is preferable that the stopper is formed on the lower end of the rope.

Nutrient cultivation apparatus for achieving the object of the present invention is provided with a moving means for periodically moving the nutrient solution cultivation port having a culture soil for supporting the crops on a predetermined path, and at one point on the moving path of the nutrient solution cultivation port And a spray nozzle for supplying the nutrient solution from the top to the nutrient solution cultivation port passing through the point, and a nutrient solution recovery channel for recovering the nutrient solution discharged from the nutrient solution cultivation port.

The moving means is preferably a chain conveyor equipped with a plurality of nutrient solution cultivation port at regular intervals.

The nutrient solution growing device includes at least two chain conveyors arranged in a direction substantially perpendicular to the moving direction of the nutrient solution growing port, and moves the chain conveyor in a direction substantially perpendicular to the moving direction of the nutrient solution growing port. It is preferable that a gap adjusting means is further provided.

The gap adjusting means includes at least one rail arranged in a direction substantially perpendicular to the moving direction of the nutrient solution cultivation port, at least one roller member provided at a lower end of the chain conveyor and movable on the rail, and the chain conveyor. It is preferable to have a drive mechanism for imparting a driving force to the rail direction.

Hereinafter, with reference to the accompanying drawings will be described in detail preferred embodiments of the nutrient solution cultivation port and nutrient solution cultivation device according to the present invention.

1 and 2, the nutrient solution cultivation apparatus 100 according to the present embodiment is a moving means for periodically moving a plurality of nutrient solution cultivation port 1 on a predetermined path, and nutrient solution cultivation port (1) And a nutrient solution recovery channel (reference numeral 12 in FIG. 11) for recovering the nutrient solution discharged from the nutrient solution cultivation port. The nutrient solution recovery channel is a component that is supplied to the nutrient solution cultivation port (1) to recover the nutrient solution used by the crop and discharged to the bottom thereof for preventing and reusing environmental pollution.

The moving means is composed of a chain conveyor system. The chain conveyor system is wound around two chain wheels 31 and 31 '(drive side chain wheel and driven side chain wheel) installed at both ends and teeth 31a around the chain wheels 31 and 31'. The hook is provided with a power transmission means including a chain 33 and a motor 32 for powering the drive side chain wheel 31.

In the present specification, only a chain conveyor is described as a moving means of the nutrient solution cultivation port, but a rope transmission means or a belt transmission means may be used in addition to the chain transmission means. In addition, although the motor 32 is configured to transmit power only to the drive side chain wheel 31 in the present embodiment, when the length of the chain conveyor is considerably long, the drive side chain wheel 31 and the driven side for smooth driving. It is also possible to supply power to the chain wheel 31 'at the same time.

The two chain wheels 31 and 31 'are interconnected by a cross support 37 on which a motor 32 is mounted, and two C-shaped pipes 34 extending substantially parallel to the cross support 37. It will be described later) is configured to guide the movement of the chain (33). In addition, the two C-shaped pipes 34 are connected to each other by a plurality of longitudinal supports 35 arranged at predetermined intervals. The chain wheels 31, 31 ′ and the vertical support 35 are fixed to the lower support 38 installed under the chain conveyor system by a plurality of vertical supports 36 arranged at predetermined intervals. The lower support 38 is provided with a conveyor gap adjusting means as described later.

As shown in FIG. 2, the chain conveyor 100 may be provided with a plurality of sets as long as space in the facility house permits. The arrangement direction of the plurality of chain conveyors 100 is a direction substantially perpendicular to the moving direction (“Y” direction) of the nutrient solution cultivation port 1 (“X” direction). In the case where a plurality of chain conveyors 100 are integrated and arranged in the facility house as described above, it is preferable that a gap adjusting means is provided to adjust the distance D between the chain conveyor and the chain conveyor.

The gap adjusting means is configured to move the chain conveyor 100 as a whole in the "X" direction, as shown in Figures 1 and 5. In more detail, a plurality of rails 41 are disposed on the ground in the facility house in the "X" direction, and a plurality of roller members 42 are installed on the lower surface of the lower support 38 of the chain conveyor 100. . The roller member 42 is configured to roll along the rail 41. In addition, in order to provide a driving force in the "X" direction to the chain conveyor 100, the support member 43 is provided on each of the upper roller member 42, the shaft 44 of the length corresponding to the length of the conveyor It is placed in parallel with the lower support (38) by fitting in the support (43). The pinion gear 45, which is integrally rotated with the shaft, is fixed at a predetermined position of the shaft 44, and the pinion gear 45 is engaged with the rack gear 26 disposed thereunder. In addition, the handle 48 is supported by a supporter 49 fixed to the outermost vertical support 36 of the chain conveyor 100. Gear connecting means 47 is provided between the handle 48 and the shaft 38 to transmit the rotational force of the handle.

In the present embodiment, a technique in which an operator manually moves the conveyor in the "X" direction by rotating the handle 48 is described. However, the present invention is not limited thereto, and the nutrient solution cultivation of moving the conveyor using a driving means such as a motor is described. Note that it includes the device. In addition, the present invention does not exclude any structure other than the rack-pinion coupling described above as the power transmission means.

Hereinafter, the means for mounting the nutrient solution cultivation port 1 on the chain conveyor 100 will be described.

As shown in Figures 3 and 4, the chain conveyor of the present embodiment uses a hoist chain 33, and the nutrient solution material port 1 is mounted on the hoist chain 33 of the chain conveyor 100. That is, the hook 6 of the upper end of the wire rope 4 fixed with the nutrient solution culture port 1 is fixed to the hook of the hoist chain 100. At this time, when the hoist chain 33 is wound around the chain wheel 31 as shown clearly in FIG. 3, the hook 6 of the wire rope 4 is formed on the outer circumference of the chain wheel 31. ) To form an interference prevention groove 31b under the teeth 31a of the chain wheel 31. C-shaped pipe (34) for guiding the movement of the chain (33) is open to provide a path through which the rope (4) of the nutrient solution cultivation port (1) moves.

Hereinafter, the operation of the nutrient solution cultivation apparatus according to the embodiment.

The nutrient solution cultivation port 1 is fixed on the hoist chain 33 of the chain conveyor 100 at predetermined intervals. At this time, the culture soil for supporting the crop is contained in the nutrient solution cultivation port (1). When the motor 32 of the chain conveyor 100 is driven, the chain 33 drags the nutrient solution cultivation port 1 and circulates along a predetermined path. At the same time, when the injection nozzle 11 located on the movement path of the nutrient solution cultivation port 1 is operated, the nutrient solution is periodically supplied to the lower nutrient solution cultivation port 1. On the other hand, the nutrient solution flowed out from the nutrient solution cultivation port (1) is recovered by the nutrient solution recovery channel 12 of the lower.

In order to efficiently arrange the space in the facility house, when several chain conveyors 100 are to be arranged in an integrated manner, the distance D between the conveyor and the adjacent conveyor is reduced, and thus the worker's work space is insufficient. In this case, the operator generates the driving force in the "X" direction by the interaction of the pinion gear 45 and the rack gear 46 fixed on the shaft 44 by rotating the handle 48 of the gap adjusting means. Accordingly, the plurality of roller members 42 installed at the lower end of the chain conveyor 100 simultaneously move the rails 41 so that the chain conveyor 100 is generally moved in the "X" direction. In this way, the operator can freely adjust the distance D between the conveyors.

6 and 7 show another embodiment of the nutrient solution cultivation apparatus according to the present invention. Detailed descriptions of the same elements as those of the nutrient cultivation apparatus of FIGS. 1 to 5 will be omitted from the technical configuration and effect of the nutrient cultivation apparatus of FIGS. 6 and 7.

The embodiment shown in Fig. 6 uses a chain conveyor employing a chain 33 'in which a link plate is continuously coupled to a pin. In particular, in the present embodiment, by using the multi-row chain, the first row 33'a located at the upper side is engaged with the sprockets (not shown) of the chain wheels disposed at both ends of the chain, and the second row ( 33'b) is to fix the upper end of the wire rope 4 'fixing the nutrient solution cultivation port 1. In addition, in this embodiment, since the side surface of the C-shaped pipe 34 'guiding the movement of the chain 33' is opened, the wire rope 4 'is also bent in a "U" shape to correspond thereto.

The nutrient solution growing device shown in Fig. 7 adopts an I-shaped beam 34 "as a member for guiding the movement of the chain 33". Roller members 51 may be provided on both sides of the I-shaped beam 34 ″ to move along the longitudinal direction of the I-shaped beam 34 ″. The rope 4 ″ fixing the nutrient solution cultivation port 1 is It is coupled on the roller member 51. The chain 33 "is engaged with the roller member 51 by the conventional coupling means, so that the roller member 51 moves a predetermined path in response to the movement of the chain 33". Will be moved accordingly.

8 to 10 show another embodiment of the nutrient solution cultivation apparatus according to the present invention, which is provided with an improved apparatus as a means for mounting the nutrient solution cultivation port on the chain conveyor.

That is, in this embodiment, unlike the embodiment shown in Figures 1 to 5, the nutrient solution cultivation port (1) is seated on the pallet 201 that circulates the path on the chain conveyor 200 and the pallet 201 It is configured to move together. The chain conveyor 200 of the present embodiment includes a frame 207 extending along the movement path of the nutrient solution cultivation port 1, two guide rails 208 installed along the movement path on the frame 207, and the guide rail. Roller 202 moving along the respective 208 and the pallet 201 is fixed to the upper portion, the C-shaped pipe installed in the frame 207 along the movement path to guide the movement of the chain 203 therein ( 204, a fixing member 209 for coupling the chain 203 and the pallet 201, and a chain wheel 205 driven by a predetermined driving means (not shown) and wound with the chain 203. Equipped.

When the pallet 201, in which the nutrient solution refilling port 1 is seated, passes through the curved portion of the movement path (the portion where the chain wheel 205 is located in FIG. 10), it may interfere with the adjacent pallet. In order to prevent this, a circular chamfer is formed in a portion of the pallet 201 toward the center of the radius of curvature of the curved portion. In addition, means for coupling adjacent pallets to each other, that is, a ring 201b and a clasp 201c, are provided on both sides of the pallet to prevent flow during movement of the pallet.

In addition, one side of the frame 207 is formed with a groove 210 along the movement path to perform the function of collecting the nutrient solution discharged from the nutrient solution cultivation port (1). A groove 201a is formed along the outer circumference of the pallet 201 so that the nutrient solution flowing out of the nutrient solution cultivation port 1 flows into the groove 210 under the pallet.

Although not shown, the apparatus of the present embodiment may be provided with means for adjusting the distance between the plurality of chain conveyors in the same manner as the nutrient solution cultivation device of Figures 1 to 5, the technical configuration of the gap adjusting means is Since it is substantially the same as the technical configuration shown in Figure 5 to the detailed description thereof will be omitted.

Hereinafter, embodiments of the stacked nutrient solution cultivation port according to the present invention will be described in detail with reference to FIGS. 11 to 17.

As shown in Fig. 11, the stacked nutrient cultivation port 1 of the present embodiment is hung on a plurality of conveyors of the nutrient cultivation apparatus. That is, the nutrient solution recovery channel 12 is disposed below the conveyor path 7 installed in the facility house, and the color recovery channel 12 passes through the filtration device 9, the nutrient solution storage tank 8, and the pump 10. It is connected to the nutrient solution injection nozzle (11). The nutrient solution discharged from the stacked nutrient solution cultivation port 1 is recovered in the nutrient solution recovery channel 12, filtered by the filtration device 9, and stored in the nutrient solution storage tank 8. The nutrient solution stored in the nutrient solution storage tank 9 at the time of nutrient solution injection is pumped by the pump 10 and is supplied to the nutrient solution cultivation port 1 passing through the lower part through the injection nozzle 11.

12 and 13, the stacked nutrient solution cultivation port is formed by stacking a plurality of nutrient solution cultivation ports (1). Each of the nutrient cultivation port 1 has a cylindrical shape of a rectangular cross section, the upper and lower portions are open as shown in FIG. The bottom opening portion 1d of the culture soil 3 is installed at the lower opening of the nutrient cultivation port 1, and the crop growth zone or seed inlet 1a is formed at the side of the nutrient cultivation port 1. The crop growth zone or seed inlet (1a) is a function to easily put the seed of the crop in the culture soil (3) and when the seed of the crop grown in the culture soil (3) the leaf portion of the nutrient solution cultivation port It performs a function that provides a space to escape to the outside.

A rope through hole 1e is formed in the center of the bottom network 1d of the nutrient solution growing port 1. The rope through-hole (1e) is passed through the wire rope to be fixed by hanging the nutrient solution cultivation port.

An upper jaw 1b is formed at an upper portion of the nutrient solution growing port 1, and a lower jaw 1c is formed at a lower portion of the nutrient solution growing port 1. The upper jaw 1b and the lower jaw 1c are sized so that the lower jaw 1c of the upper nutrient cultivation port is engaged with the upper jaw 1b of the lower nutrient cultivation port when the plurality of nutrient solution cultivation ports are stacked. (See Fig. 13). In addition, a pot drain port 1f is provided on the outer bottom of the lower jaw 1c of the nutrient solution growing port 1.

As shown in Fig. 15, in this embodiment, the upper cover 2 is mounted on the upper part of the nutrient solution cultivation port located at the top of the stacked nutrient solution cultivation port. In addition, the lower cover (2) made of the same shape as the upper cover is also mounted on the lower portion of the nutrient solution cultivation port located at the bottom end. The upper cover and the lower cover 2 has a shape corresponding to the nutrient solution cultivation port 1, and is made of a funnel type (2e: hopper type) whose cross-sectional area gradually decreases from the upper portion to the lower portion. A cover net 2b is installed at the lower part of the upper and lower covers 2, and a rope fastening hole 2c is formed at the center of the cover net 2b. The upper part of the upper and lower cover (2) is formed with a cover upper end frame (2a) coupled to the lower jaw (1c) of the nutrient solution cultivation port 1 to be stacked on the top, the nutrient solution to be stacked on the bottom A cover lower end 2d coupled to the upper jaw 1b of the port 1 is provided. In addition, the cover dripping opening 2f is formed in the cover upper edge 2a.

The cover drain port 2f of the upper and lower cover 2 and the port drain port 1f of the nutrient solution cultivation port 1 communicate with each other to provide a path from the top to the bottom of the stacked nutrient solution cultivation ports. The path guides the nutrient solution accumulated on the outer circumferential surface of the funnel 2e of the upper cover 2 downward from the nutrient solution injected from the nutrient solution injection nozzle 11.

Effects of the laminated nutrient solution cultivation port of the present embodiment having the configuration as described above are as follows.

The nutrient solution cultivation port (1) in which a plurality of nutrient solution cultivation ports (1 in this embodiment) in which each of the cultivated soils (3) is placed are sequentially stacked, and the upper cover (2) and the lower cover (2) are stacked. Mount on the top and bottom respectively. Then, the wire rope 4 is passed through the rope through hole (1e) of the nutrient solution cultivation port (1) and the rope fastening hole (2c) of the upper and lower cover (2), the wire using a wire rope stopper (5) The lower end of the rope 4 is fixed to the lower cover 2. Then, using the hook 6 provided on the top of the wire rope 4, the laminated nutrient solution cultivation port 1 is fixed to the chain 7 of the conveyor.

The laminated nutrient solution cultivation port 1 is fixed on the chain conveyor by a plurality of fixed intervals and drives the conveyor. At the same time, the nutrient solution is injected from the nutrient solution injection nozzle 11 provided in the upper portion, and the nutrient solution is supplied to the stacked nutrient solution cultivation port passing through the lower point of the nozzle. The nutrient solution sprayed on the upper cover 2 of the stacked nutrient solution cultivation port is introduced into the nutrient solution cultivation port 1 at the top through the upper cover net 2b to supply the nutrient solution to the crops planted in the culture soil therein, and to the bottom bottom network. It flows out through 1d. The spilled nutrient solution flows into the nutrient solution cultivation port 1 of the next stage. By repeating this method, the nutrient solution finally discharged from the lower cover 2 is collected in the nutrient solution recovery channel 12 and flows back into the nutrient solution storage tank 8 through the filtration device 9 to reuse the nutrient solution.

16 and 17 show another embodiment of the nutrient solution cultivation port according to the present invention.

In the nutrient cultivation port 8 shown in Fig. 16, crop growth spheres 8a are formed on four outer surfaces of a rectangular cross section, respectively. Nutrient cultivation port 9 shown in Fig. 17 has a circular cross section in which four crop growth zones 9a are formed. Nutrient cultivation port (8, 9) of the present embodiment is different from the nutrient cultivation port (1) of the embodiment shown in Figure 14 only in the number and cross-sectional shape of the crop growth zone, other technical configuration is the same, Detailed description will be omitted.

The present invention is not limited to the nutrient solution cultivation port of the specific shape disclosed in the specification and drawings, it can be adopted nutrient solution cultivation port of various shapes (for example, triangle, hexagon) depending on the conditions of use. The number of crop growth areas formed on the side of the nutrient solution cultivation port may also be set in various ways according to the actual situation of the crop cultivation site.

In the stack-type nutrient cultivation port according to the present invention can be arbitrarily adjusted the number of nutrient solution cultivation port according to the height of the facility house, it is possible to observe the growth process of the crop by lifting each stage during nutrient cultivation. Therefore, since the space in the facility house can be used efficiently, high integration of crop cultivation is possible.

In the nutrient cultivation device according to the present invention, since the nutrient solution cultivation port is often changed in the facility house, even if the sunscreen facility such as the ceiling is not changed from time to time, the amount of sunshine incident to the crop is maintained uniformly, and thus, even growth of the crop is achieved. Contribute.

In addition, in the present invention, there is no need to install a nutrient solution irrigation facility for each nutrient solution cultivation port, there is an advantage that the installation cost is saved. The nutrient solution leaked from the nutrient solution cultivation port is reused by the nutrient solution recovery channel, thereby preventing waste of nutrient solution.

1 is a partially cutaway perspective view of an embodiment of the nutrient solution cultivation apparatus according to the present invention,

Figure 2 is an overall configuration of an embodiment of the nutrient solution cultivation apparatus according to the present invention,

3 and 4 is a partially cutaway perspective view of the chain conveyor of the nutrient solution cultivation device of Figure 1,

Figure 5 is a perspective view of the conveyor residual adjustment means of the nutrient solution cultivation device of Figure 1,

Figure 6 and Figure 7 is a perspective view showing another embodiment of the nutrient solution cultivation port mounting structure of the nutrient solution cultivation apparatus according to the present invention,

8 is a plan view showing another embodiment of the nutrient solution cultivation apparatus according to the present invention,

FIG. 9 is a cross-sectional view taken along the line “A-A” of FIG. 8.

10 is a partially cutaway perspective view of the nutrient solution culturing device of FIG. 8;

11 is a configuration diagram showing a state of use of one embodiment of the stacked nutrient solution cultivation port according to the present invention,

Figure 12 is a perspective view of one embodiment of the stacked nutrient solution cultivation port according to the present invention,

Figure 13 is a cross-sectional view of the stacked nutrient solution culture port of Figure 12,

14 is a perspective view showing one nutrient solution cultivation port of the stacked nutrient solution cultivation port of FIG.

FIG. 15 is a perspective view of the upper and lower covers of the stacked nutrient solution growing port of FIG. 12;

Figure 17 is a perspective view of another embodiment of a stacked nutrient solution culture port according to the present invention.

** Explanation of symbols for the main parts of the drawings

1: Nutrient Solution Port 2: Upper Cover (Lower Cover)

3: culture soil 4: wire rope

5: stopper 6: hook

8: Nutrient Storage Tank 9: Filtration System

10; Circulation Pump 11: Nutrient Injection Nozzle

12: Nutrient recovery channel 31, 31 ': Chain wheel

33: chain 34: C-shaped tube

48: handle 100: chain conveyor

Claims (4)

Moving means for periodically moving a nutrient solution cultivation port having a culture soil supporting a crop on a predetermined path; An injection nozzle installed at one point on the movement path of the nutrient solution cultivation port and supplying nutrient solution from the top to the nutrient solution cultivation port passing through the point; A nutrient solution cultivation device comprising a nutrient solution recovery channel for recovering the nutrient solution discharged from the nutrient solution cultivation port. The nutrient cultivation device according to claim 1, wherein the moving means is a chain conveyor equipped with a plurality of nutrient solution cultivation ports at regular intervals. According to claim 1, wherein the nutrient solution cultivation device has at least two or more chain conveyors arranged in a direction substantially perpendicular to the moving direction of the nutrient solution cultivation port, The nutrient solution cultivation device further comprises a gap adjusting means for moving the chain conveyor in a direction substantially perpendicular to the moving direction of the nutrient solution cultivation port. The method of claim 3, wherein the gap adjusting means, At least one rail arranged in a direction substantially perpendicular to a moving direction of the nutrient solution growing port; At least one roller member provided at a lower end of the chain conveyor and movable on the rail; And a driving mechanism for imparting a driving force in the rail direction to the chain conveyor.