KR20230174623A - Hydroponics apparatus with nutrient water level control device - Google Patents

Abstract

The present invention relates to a hydroponic plant cultivation device equipped with a water level control mechanism, and more specifically, in hydroponic cultivation of plants, a nutrient solution supply gutter ( gutter) and a water level control mechanism that is vertically coupled to the discharge end cap of the gutter and adjusts the water level of the supplied culture medium to increase the efficiency of hydroponic cultivation and provide effective cleaning of sludge accumulated on the bottom of the gutter of the grower. It's about.
A hydroponic plant cultivator equipped with a water level control mechanism according to an embodiment of the present invention includes a gutter, an end cap coupled to the supply side and a discharge side of the gutter, a cover coupled to an upper part of the gutter, and an end cap on the discharge side. The water level adjustment mechanism is coupled, and the water level adjustment mechanism is inserted into the upper center of the perforated end cap on the discharge side, and the water level adjustment mechanism is supported and coupled to the bottom of the end cap.

Description

Hydroponic plant cultivation apparatus equipped with a water level control device {Hydroponics apparatus with nutrient water level control device}

The present invention relates to a hydroponic plant cultivation device equipped with a water level control mechanism, and more specifically, in hydroponic cultivation of plants, a nutrient solution supply gutter ( gutter) and a water level control mechanism that is vertically coupled to the discharge end cap of the gutter and adjusts the water level of the supplied culture medium to increase the efficiency of hydroponic cultivation and provide effective cleaning of sludge accumulated on the bottom of the gutter of the grower. It's about.

Unless otherwise indicated herein, the material described in this section is not prior art to the claims of this application, and is not admitted to be prior art by inclusion in this section.

In general, there are various cultivation systems in hydroponics, but in actual cultivation, the deep flow technique (DFT) developed in Japan and the nutrient flow or film technique (NFT) developed in the UK are widely used. It is happening.

The above liquid hydroponics system (DFT) can be interpreted as a liquid circulation hydroponics, which is a hydroponic cultivation method in which the entire root or part of it is submerged in a culture medium. Therefore, the bed (cultivation tank, cultivation tank, cultivation device) that collects the culture fluid needs to be manufactured with high strength and is composed of plastic or foamed styrofoam and waterproof film.

This liquid hydroponic method (DFT) has a large amount of culture medium in the cultivation bed, so it can reduce fluctuations in the root zone environment and make it easy to control the temperature of the culture medium, but the capacity of the bed or tank must be increased and power costs are high. Since a significant portion of the roots are submerged in the culture medium, the supply of nutrient solution is high, but it is difficult to supply sufficient oxygen to the cultivated plants, and the roots of the plants are always in contact with the nutrient solution, resulting in excessive moisture and severe root rot, which is bad for the growth of the plant. There are also disadvantages.

On the other hand, thin film hydroponic system (NFT) is a hydroponic cultivation method carried out with culture medium flowing in shallow water, and the basic structure of the system consists of channels of the cultivation bed, culture medium tank, and liquid supply pump. It is a hydroponics method that systematizes the supply of water, nutrients, and oxygen necessary for growth in the simplest form.

The channel that becomes the cultivation bed of this thin film hydroponic method (NFT) must have a slope for the plants to grow roots. Because the depth of the nutrient solution flowing down the channel is shallow and most roots are exposed to the air, oxygen supply to the roots occurs naturally. The larger the slope (gradient) of the channel, the better the flow of the culture medium, but from a practical construction or cultivation management perspective, it is known that a range of 1/70 to less than 1/100 is appropriate.

The above thin-film hydroponic system (NFT) does not allow the culture solution to accumulate in the channel, so it is lightweight and can be easily installed on a high floor even if the frame strength is low. Since the depth of the nutrient solution flowing down is shallow, most roots are exposed to air. It has the advantage of being exposed to sufficient oxygen supply, but the disadvantage is that if the culture medium flows shallowly in the channel during a period when the root group of the cultivated plant is not developing, the plant cannot absorb the nutrient solution sufficiently, causing wilting and poor growth. there is.

Meanwhile, a hydroponic cultivation device using an intermittent nutrient solution supply method has been disclosed in Domestic Registered Patent No. 10-2276043. This method is also intended to improve the problems of the submerged liquid hydroponic method (DFT) and is intermittently located on the upper side. The nutrient solution is supplied only to the cultivation bed for cultivation, and is sequentially supplied to the cultivation bed below. Although this may be a partial improvement, it still does not solve all the shortcomings of the liquid hydroponic method (DFT) and the thin film hydroponic method (NFT). will be.

Korean Patent No. 10-2276043 (announced on July 13, 2021)

The present invention is intended to be improved in consideration of the above-described conventional problems.

In other words, considering all the problems of the prior art and the pros and cons of the liquid hydroponic method (DFT) and the thin film hydroponic method (NFT), an improved hydroponic method was developed to suit the characteristics and circumstances of the cultivated plants, and the disadvantages of the two hydroponic methods were developed. It is intended to resolve.

The problem to be solved as a key issue of the present invention is to control the height of the culture medium supplied to hydroponic plants, which can be applied to both the liquid hydroponic method (DFT) and the thin film hydroponic method (NFT), by using a water level control mechanism to control the hydroponic plants. The purpose is to provide effective growth and growth.

In addition, another purpose of the present invention is to improve the efficiency of hydroponic cultivation than before by integrating the gutter corresponding to the cultivation bed from the existing 1-way channel to a 2-way channel.

Another object of the present invention is to provide a water level control mechanism that can control the water level of the culture medium up to the bottom of the gutter and easily clean sediments such as sludge accumulated on the bottom.

In addition, the present invention forms the openings of the cover placed on the gutter into three types of openings: large, medium, and small, making it possible to adjust the planting spacing for each cultivation stage, from the seedling stage to the planting and harvesting stages. Another purpose is to provide a cover that can minimize movement of crops and improve the efficiency of hydroponic cultivation operations.

In the present invention, the above nutrient solution supply method can be called an adjustable swallow flow technique (ASFT). The above-mentioned ASFT device can be applied to all nursery stands, cultivation stand gutters, and guards (end caps). This applies not only to the cultivation gutters of plant factories but also to the gutters of smart farms for houses. This seems possible.

In addition, it is not limited to the technical challenges described above, and it is obvious that other technical challenges may be derived from the description below.

A hydroponic plant cultivator equipped with a water level control mechanism according to an embodiment of the present invention includes a gutter, an end cap coupled to the supply side and a discharge side of the gutter, a cover coupled to an upper part of the gutter, and an end cap on the discharge side. The water level adjustment mechanism is coupled, and the water level adjustment mechanism is inserted into the upper center of the discharge-side end cap, and the water level adjustment mechanism is supported and coupled to the bottom of the end cap.

According to a preferred embodiment of the present invention, the water level control mechanism is characterized in that it is formed in a three-stage structure in the shape of a circular pillar at the top, center, and bottom.

According to a preferred embodiment of the present invention, the vertical handle formed at the top of the water level adjustment mechanism is installed upright on the central upper surface of the rotating disk portion having a position indicator on one side, and is located on the lower side of the central end of the water level adjustment mechanism. A pair of left and right openings are formed, a pair of lower left and right openings are formed at the lower end of the water level adjustment mechanism, and the upper end of the water level adjustment mechanism is installed vertically and integrally with the upper center of the end cap. The lower end of the water level adjustment mechanism is fitted and coupled to the outside of the central space of the cylinder, which is integrally installed perpendicular to the center of the bottom of the end cap, and the bottom is perpendicular to the bottom. The cylinder is characterized by a pair of left and right openings cut into the bottom.

According to a preferred embodiment of the present invention, the pair of openings formed at the central end of the water level adjustment mechanism and the pair of cut openings formed at the bottom of the water level adjustment mechanism are opened or closed by rotation of the vertical handle. It is characterized by being

According to a preferred embodiment of the present invention, the gutter is characterized in that a pair of left and right 2-way nutrient solution supply channels are integrally formed with a central wall in between.

According to a preferred embodiment of the present invention, the both side end caps are characterized in that grooves are formed that fit into the gutter and enable distance adjustment.

According to a preferred embodiment of the present invention, the discharge pipe on the discharge side of the gutter has a bottom portion of the discharge end cap and a central portion of the gutter fitted into the groove formed with continuous perforations and connected in communication with the lower end of the water level adjustment mechanism. It is characterized by discharge of nutrient solution.

According to a preferred embodiment of the present invention, the cover is shaped like a W, and the inner groove of the protrusion of the cover is fitted on the protrusion of the central wall of the gutter, and the left and right planes of the cover protrusion continuously cover the channels on both sides of the gutter in the longitudinal direction. However, it is characterized in that a plurality of open holes are formed on the left and right planes of the cover in which a plurality of cultivation pots for hydroponic plants are placed.

According to a preferred embodiment of the present invention, the cover covers the gutter in one or more pieces, and the number of open holes in which the redistribution of the cover is placed is characterized in that it is composed of three types: large, medium, and small.

According to a preferred embodiment of the present invention, the redistribution port is characterized in that the lower part is open and long holes are formed on all sides.

According to a preferred embodiment of the present invention, the gutter is inclined from the supply side to the discharge side, and the inclination is characterized in that it has a gradient in the range of 1/100 to 3/1000.

According to the present invention, effective growth and growth of hydroponic plants can be achieved by controlling the height of the culture medium supplied to hydroponic plants, which can be applied to both liquid hydroponic systems (DFT) and thin film hydroponic systems (NFT), using a water level control mechanism. It has an effect.

According to the present invention, the efficiency of hydroponic cultivation is improved compared to before by integrating the gutter corresponding to the cultivation bed from the existing 1-way channel to a 2-way channel.

According to the present invention, there is an effect of providing a water level control mechanism that can control the water level of the culture medium up to the bottom of the gutter, which is a cultivation bed, and can easily clean sediments such as sludge accumulated on the bottom.

In addition, in the present invention, the openings of the cover placed on the gutter are formed in three types of openings: large, medium, and small, making it possible to adjust the planting spacing for each cultivation stage, so that the crops can be grown from the seedling stage to the planting and harvesting stage. It has the effect of providing a cover that minimizes movement and improves the efficiency of hydroponic cultivation work.

The effect of the present invention is not limited to the above effects, and the effect of the present invention is not limited to the above effect.

It should be understood to include all effects that can be inferred from the composition of the invention as set forth in the detailed description or claims.

Figure 1 is a front perspective view (a), a rear perspective view (b), and a perspective view with the cover partially open (c) of a hydroponic plant cultivator equipped with a water level control mechanism according to an embodiment of the present invention. Perspective view with the cover fully open (d), perspective view with three types of covers (e).
Figure 2 is a perspective view of a water level adjustment mechanism (a), a gutter (b), a discharge side end cap (c), a cover (d), and a redistribution port (e) according to an embodiment of the present invention.
Figure 3 is a perspective view of a combination of a water level adjustment mechanism and an end cap according to an embodiment of the present invention.
Figure 4 is a diagram showing the operating state of the water level adjustment mechanism and the end cap according to an embodiment of the present invention.
Figure 5 is an overall conceptual diagram of a hydroponic cultivation device according to an embodiment of the present invention.

Hereinafter, a hydroponic plant cultivator equipped with a water level control mechanism according to a preferred embodiment will be examined in detail with reference to the attached drawings.

For reference, in the drawings below, each component is omitted or schematically shown 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.

Figure 1 is a front perspective view (a), a rear perspective view (b), and a perspective view with the cover partially open (c) of a hydroponic plant cultivator equipped with a water level control mechanism according to an embodiment of the present invention. A perspective view (d) with the cover fully open and a perspective view (e) with three types of covers covered, and Figure 2 shows a water level adjustment mechanism (a), a gutter (b), and a discharge end cap (c) according to an embodiment of the present invention. ), a perspective view of the cover (d), and the redistribution port (e), Figure 3 is a perspective view of the water level control mechanism and the end cap combined according to an embodiment of the present invention, and Figure 4 is a water level according to an embodiment of the present invention. This is a diagram of the operating state of the control mechanism and the end cap, and Figure 5 is an overall conceptual diagram of the hydroponic cultivation device according to an embodiment of the present invention.

When an embodiment of the present invention is described with reference to Figures 1 and 2, the hydroponic plant cultivator of the present invention includes a gutter 100 and an end cap coupled to the supply side 110 and discharge side 120 of the gutter 100 ( 200) and a cover 300 coupled to the upper part of the gutter 100, a water level adjustment mechanism 400 coupled to the discharge side end cap 220, and the water level adjustment mechanism 400 is connected to the discharge side end cap ( 220), and the water level adjustment mechanism 400 is supported and coupled to the bottom of the end cap 220.

As shown in Figures 1 and 2, the gutter 100 of the hydroponic plant cultivator equipped with the water level control mechanism 200 of the present invention is formed with two channels on both left and right sides, making it more efficient than conventional hydroponic plant cultivation. Plant cultivation is possible, and the supply side 110, which is both ends of the gutter 100, is where the nutrient solution is supplied and the opposite discharge side 120 is where the nutrient solution is discharged. End caps are attached to both left and right ends of the gutter 100. (210, 220) are coupled, and the gutter 100 is structured to be fitted into the groove 111 of the end caps 210 and 220.

In addition, a cover 300 is inserted into the upper part of the gutter 100 and coupled to the protrusion 131 of the central wall 130 of the gutter 100, and the cover 300 has a plurality of open holes 311. A redistribution port 310 having a redistribution port 310 is formed, and a central protrusion 320 having a protruding groove 321 to which the central wall 130 of the gutter 100 is coupled is formed in the center of the cover 300, and both sides In connection with this, left and right protruding portions 330 and 340 having left and right protruding grooves 331 and 341 are formed.

In addition, end caps 200 are each coupled to the supply side 110 and discharge side 120 of the gutter 100, and the coupling is between both ends of the gutter 100 in the groove portion 201 of the end cap 200. As a structure in which the gutter 100 is fitted, it may be possible to adjust its length with the gutter 100.

In addition, a cylindrical upper central cylinder 202 is installed vertically and integrally at the center of the upper part 206 of the end cap 200, and the water level adjustment mechanism 400 is interpolated and coupled thereto.

In addition, the water level control mechanism 400 interpolated into the upper central cylinder 202 of the end cap 200 is installed integrally with its lower end 430 perpendicular to the center of the bottom 205 of the end cap 200. It is fitted and coupled to the outside of the central space of the bottom central cylinder 203.

In addition, the vertical central cylinder 203 of the bottom 205 of the end cap 200 forms a pair of cut left and right openings 204, and the openings 204 are located at the bottom of the water level adjustment mechanism 400. It may be formed at the same location as the opening 423 of (430).

In addition, the water level adjustment mechanism 400 coupled to the end cap 200 is formed in a three-stage structure in the shape of a circular pillar of the upper end 410, the central end 420, and the lower end 430, and the upper end 410 A rotating disk portion 412 having a vertical handle 411 and a position indicator 413 is formed, and a pair of left and right openings 421, 422, 431, and 432 are provided at the central end 420 and the lower end 430, respectively. ) is formed, and these openings are combined with a pair of left and right openings 204 of the vertical central cylinder 203 formed on the bottom 205 of the discharge end cap 220 to control the discharge of the nutrient solution to form the gutter 100. ) can control the level of the nutrient solution contained in the nutrient solution.

According to a preferred feature of the present invention, the water level control mechanism 400 may be formed in a three-stage structure in the shape of a circular pillar including an upper end 410, a central end 420, and a lower end 430.

According to a preferred feature of the present invention, the vertical handle 411 formed on the upper end 410 of the water level adjustment mechanism 400 is integrally with the central upper surface of the rotating disk portion 412 having a position indicating portion 413 on one side. It is installed upright, and a pair of left and right openings 421 and 422 are formed on the lower side of the central end 20 of the water level adjustment mechanism 400, and left and right openings 421 and 422 are formed on the lower side 430 of the water level adjustment mechanism 400. A pair of lower openings 431 and 432 are formed, and the upper end 410 of the water level adjustment mechanism 400 is the center of a cylinder integrally installed perpendicular to the upper center of the end cap 200. It is interpolated and coupled within the space, and the lower end 430 of the water level adjustment mechanism 400 is a central space of the cylinder 203 that is integrally installed perpendicular to the center of the bottom 205 of the end cap 200. It is fitted and coupled to the outside, and the vertical cylinder 203 of the bottom part 205 is formed with a pair of left and right openings 204 cut into the bottom part 205.

According to a preferred feature of the present invention, the pair of openings 421 and 422 formed at the central end 420 of the water level adjusting mechanism 400 and the one formed at the lower end 430 of the water level adjusting mechanism 400 The pair of cut openings 431 and 432 slide across the pair of openings 204 of the vertical central cylinder 203 at the bottom 205 of the discharge side end cap 220 by rotating the vertical handle, thereby releasing the nutrient solution. You can open it to discharge it or close it to maintain the liquid state or control the water level.

According to a preferred feature of the present invention, the height of the nutrient solution supplied to hydroponic plants applicable to both the deep liquid hydroponic system (DFT) and the thin film hydroponic system (NFT) is adjusted according to the control of the water level control mechanism 400, thereby controlling the water level control mechanism 400. It can provide effective growth and growth of cultivated plants.

According to a preferred feature of the present invention, the gutter 100 can be integrally formed with a pair of left and right 2-way nutrient solution supply channels 101 and 102 with the central wall 130 in between, and thus more efficient than before. It has the advantage of being efficient in hydroponic cultivation.

According to a preferred feature of the present invention, the both side end caps 200 may be formed with grooves 201 that fit into the gutter 100 to adjust the distance.

According to a preferred feature of the present invention, the discharge pipe 140 on the discharge side 120 of the gutter 100 is fitted into the bottom 205 of the discharge side end cap 220 and the groove 201. ) is continuously perforated in the central part and is connected in communication with the lower end 430 of the water level control mechanism 400 so that the nutrient solution can be discharged.

According to a preferred feature of the present invention, the cover 300 has a W shape, and the inner groove 321 of the central protrusion 320 of the cover 300 is formed on the protrusion 131 of the central wall 130 of the gutter 100. This is fitted, and the left and right planes of the central protrusion 320 continuously cover the channels 101 and 102 on both sides of the gutter 100 in the longitudinal direction, and a plurality of hydroponic plants are placed on the left and right planes of the cover 300. A plurality of open holes 311 in which the redistribution port 500 is placed may be formed.

According to a preferred feature of the present invention, the cover 300 covers the gutter 100 in one or more pieces, and the number of open holes 311 in which the redistribution port 500 of the cover 300 is placed is: It can be composed of three forms: medium and small.

According to a preferred feature of the present invention, the redistribution port 500 may have an open bottom and long holes 510 formed on all four sides.

According to a preferred feature of the present invention, the gutter 100 is inclined from the supply side 110 to the discharge side 120, and the inclination may be in the range of 1/100 to 3/1000. Accordingly, when the culture medium is supplied to the supply side 110, it flows along the inclined gutter 100. At this time, the vertical handle 411 controls and adjusts the openings 421, 422, 431, and 432 of the water level control mechanism 400. By doing so, the water level of the nutrient solution can be controlled and the growth and growth of hydroponic plants can be effectively provided.

Meanwhile, regarding the inclination of the gutter 100, the larger the inclination (gradient) of the conventional channel, the better the flow of the culture medium, but from the perspective of practical construction or cultivation management work, it is in the range of 1/70 to less than 1/100. It is known to be appropriate, but in the present invention, as a result of numerous experiments, it was found that it is desirable to have the slope in the range of 1/100 to 3/1000.

Next, the coupling relationship and operating state of the water level control mechanism 400 and the discharge side end cap 220 according to a preferred embodiment of the present invention will be described with reference to Figures 3 and 4.

As shown in Figures 3 and 4, the water level adjustment mechanism 400 of the present invention is coupled to the discharge side end cap 220, and the water level adjustment mechanism 400 is positioned directly below the center upper part of the end cap 220. It is inserted into the inner space of the central cylinder 203, and is then fitted and coupled to the outside of the vertical central cylinder 203 integrally formed in the center of the bottom 205 of the end cap 220.

At this time, by rotating the vertical handle 411 left and right, the openings 431 and 432 of the water level adjustment mechanism 400 slide and cross the pair of openings 204 of the vertical central cylinder 203 of the end cap 220. As a result, the water level can be adjusted by controlling the discharge of the nutrient solution as the opening is opened or closed.

Figure 5 is an overall conceptual diagram of the device in which the hydroponic plant cultivator equipped with the water level control mechanism of the present invention is installed. Looking at its operating state, when the culture medium in the tank is driven by the pump (p) and supplied to the cultivator, the present invention Nutrient solution flows into the gutter 100 on the supply side 110 of the cultivator equipped with a water level control mechanism, and the gutter 100, which has a slope of approximately 1/100 to 3/1000, is installed in a zigzag manner so that the nutrient solution flowing into it is It passes through the cultivation period while supplying nutrients to hydroponic plants by repeating inflow and supply in a zigzag manner.

Preferred embodiments of the present invention will be described with reference to the attached drawings.

However, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing the present application, various methods that can replace them are available. It should be understood that equivalents and variations may exist. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims described later rather than the detailed description, and the meaning and scope of the claims and their All changes or modified forms derived from the equivalent concept should be construed as falling within the scope of the present invention.

100: gutter, 101: left channel, 102: right channel, 110: supply side, 120: discharge side, 130: center wall, 131: center wall protrusion, 140: left wall, 141: right wall, 150: discharge pipe.
200: End cap, 201: Groove, 202: Upper central cylinder, 203: Bottom central cylinder, 204: Opening, 205: Bottom, 206: Upper, 210: Empty side end cap, 220: Discharge side end cap
300: cover, 311: multiple openings, 320: central protrusion, 321: central protrusion groove, 330: left protrusion, 331: left protrusion groove, 340: right protrusion, 341: right protrusion groove.
400: water level adjustment mechanism, 410: top of water level adjustment mechanism, 411: vertical handle, 412: rotating disk part, 413: position indicator, 420: center end of water level adjustment mechanism, 421: left opening at the center end, 422: right opening at the center end , 430: lower part of water level control mechanism, 431: lower left opening, 432: lower right opening
500: redistribution port, 510: long hole

Claims (11)

gutter;
End caps coupled to the supply and discharge sides of the gutter;
A cover coupled to the top of the gutter;
A water level control mechanism coupled to the discharge end cap;
The water level adjustment mechanism is inserted into the upper center of the discharge side end cap,
A hydroponic plant cultivator with a water level control mechanism, wherein the water level control mechanism is supported and coupled to the bottom of the end cap. The hydroponic plant cultivator with a water level control mechanism according to claim 1, wherein the water level control mechanism is formed in a three-stage structure in the shape of a circular pillar at the top, center, and bottom. The method of claim 2, wherein the vertical handle formed at the top of the water level adjustment mechanism is installed upright and integrally on the central upper surface of the rotating disk portion having a position indicator on one side,
A pair of left and right openings are formed on the lower side of the central end of the water level control mechanism,
A pair of left and right lower openings are formed at the lower end of the water level control mechanism,
The upper end of the water level adjustment mechanism is interpolated and coupled within the central space of a cylinder that is integrally installed perpendicular to the upper center of the end cap,
The lower end of the water level adjustment mechanism is fitted and coupled to the outside of the central space of the cylinder, which is integrally installed perpendicular to the center of the bottom of the end cap,
A hydroponic plant cultivation device equipped with a water level control mechanism, wherein the bottom vertical cylinder is formed with a pair of left and right openings cut into the bottom. The method of claim 3, wherein the pair of openings formed at the central end of the water level adjustment mechanism and the pair of cut openings formed at the bottom of the water level adjustment mechanism are opened or closed by rotation of the vertical handle. A hydroponic plant cultivation device equipped with a water level control mechanism. The hydroponic plant cultivator with a water level control mechanism according to claim 1, wherein the gutter is integrally formed with a pair of left and right 2-way nutrient solution supply channels with a central wall in between. The hydroponic plant cultivator with a water level adjustment mechanism according to claim 1, wherein the end caps on both sides are formed with grooves that fit into the gutter to enable distance adjustment. The method of claim 6, wherein the discharge pipe on the discharge side of the gutter has a bottom portion of the discharge end cap and a central portion of the gutter fitted into the groove, and is connected in communication with the lower end of the water level control mechanism to discharge the nutrient solution. A hydroponic plant cultivation device equipped with a water level control mechanism. The method of claim 1, wherein the cover is shaped like a W and the inner groove of the protrusion of the cover is fitted on the protrusion of the central wall of the gutter, and the left and right planes of the cover protrusion continuously cover channels on both sides of the gutter in the longitudinal direction. A hydroponic plant cultivation device equipped with a water level control mechanism, characterized in that a plurality of open holes in which cultivation pots of a plurality of hydroponic plants are placed are formed on the left and right planes of the cover. The water level control device according to claim 8, wherein the cover covers the gutter in one or more pieces, and the number of open holes in which the redistribution of the cover is placed is large, medium, and small. Equipped with hydroponic plant cultivation machine. The hydroponic plant cultivator with a water level control mechanism according to claim 9, wherein the cultivation pot has an open bottom and long holes are formed on all sides. The water tank according to any one of claims 1 to 10, wherein the gutter is inclined from the supply side to the discharge side, and the incline has a gradient in the range of 1/100 to 3/1000. Plant cultivation period.