JPWO2019131233A1 - Hydroponics equipment, its filters, its methods - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hydroponic cultivation device capable of satisfactorily reducing the occurrence of insects, a filter thereof, and a method thereof. An aqueous solution is sprayed from a spray nozzle 226 onto the roots of a plant 214 planted on a planting panel 210. The remaining fog is drained from the drain port 228. The egg 504 that the insect 500 invades into the spray tank 220 and lays eggs passes through the pre-stage filter 310 of the circulation unit 300 together with the aqueous solution and is housed in the aqueous solution tank 320. Spawning may also occur in the aqueous solution tank 320. The aqueous solution in the aqueous solution tank 320 is sent to the subsequent filter 350 by the pump 340. In the subsequent filter 350, the egg 504 of the insect 500 is removed, and an aqueous solution containing no egg 504 is supplied from the pipe 304 to the water supply pipes 222 and 224. Therefore, the spray nozzle 226 sprays an aqueous solution that does not contain the egg 504. [Selection diagram] Fig. 2

Description

The present invention relates to a hydroponic cultivation device for cultivating vegetables and the like using an aqueous solution (culture solution), a filter thereof, and an improvement of the method.

As a conventional hydroponic cultivation device or method, for example, there is "hydroponic cultivation device and hydroponic cultivation method" described in Patent Document 1 below. This is applied when growing a plant with taproots and lateral roots. The taproots are irrigated by spraying a liquid in a mist form, and the lateral roots are immersed in the liquid. By irrigating and adjusting at least one of the spray interval or spray time by the taproot irrigation section to limit the amount of liquid sprayed to the taproot to the required amount, an appropriate amount of liquid can be supplied to the plant. It is the one that was made.

Japanese Unexamined Patent Publication No. 2014-150740

By the way, in the above-mentioned background technique, if an insect that lays eggs in water, especially among Diptera, enters a room filled with an aqueous solution, it may lay eggs in the deep flow and hatch and proliferate. Yes, it is not preferable in terms of hygiene management.

The present invention has focused on the above points, and an object of the present invention is to provide a hydroponic cultivation device capable of satisfactorily reducing the occurrence of insects, a filter thereof, and a method thereof.

The hydroponic cultivation device of the present invention is a hydroponic cultivation device in which a plant planted in a cultivation bed is irrigated and cultivated, and a spray tank is provided on the root side of the plant in the cultivation bed and the plant is cultivated. The spraying means includes a spraying means for spraying an aqueous solution on the roots of the plant and a circulating means for collecting the aqueous solution in the spraying tank and supplying it to the spraying means again. It is characterized in that the plant is cultivated only by spraying the aqueous solution with.

According to one of the main forms, the circulation means is provided with a filter means for removing insect eggs contained in the aqueous solution. According to another form, the filter means is arranged at a position closest to the spraying means in the circulation path of the circulation means. According to still another form, the mesh size of the filter means is 400 μm or less, preferably 200 μm to 55 μm.

According to yet another embodiment, the spraying means, the planting area 0.08 m ² ～1.0M 1 or so per ² of said plant, one preferably planting area 0.18 m ² ～0.42M ² per It is characterized by being installed at a rate of about. Alternatively, the foreign matter passing diameter in the spraying means is set to about 0.15 mm to 0.9 mm, preferably about 0.5 mm.

The hydroponic cultivation filter of the present invention is a hydroponic cultivation filter used when cultivating the plant by spraying an aqueous solution in a spray tank provided on the root side of the plant planted in the cultivation bed. It is characterized by having a function of removing insect eggs in the collected aqueous solution when the aqueous solution in the spray tank is collected and sprayed again in the spray tank.

The hydroponic cultivation method of the present invention is a hydroponic cultivation method in which a plant is irrigated and cultivated, and a spraying step of spraying an aqueous solution on the roots of the plant and a circulation step of collecting the sprayed aqueous solution and spraying it again. The plant is cultivated by spraying only the aqueous solution by the spraying step. According to one of the main forms, it comprises an egg removing step of removing eggs in an aqueous solution. The above and other objects, features and advantages of the present invention will become clear from the following detailed description and accompanying drawings.

According to the present invention, since only the solution is sprayed on the roots of the plant and the eggs of the insects are removed, the outbreak of insects can be satisfactorily reduced, and the adhesion of bacteria is also reduced. can do.

It is a figure which shows the whole of the hydroponic cultivation apparatus in one Example of this invention. (A) is a view of the inside from a plane, and (B) is a view of the inside from the side. It is a figure which shows the main part of the said Example. It is a figure which compares and shows the size of the foreign matter passing diameter of the spray nozzle 226. It is a figure which shows the other arrangement form of the spray nozzle 226.

Hereinafter, the best mode for carrying out the present invention will be described in detail based on examples.

FIG. 1 shows the overall state of the hydroponic cultivation apparatus according to this embodiment, and the main part thereof is shown in FIG. In these figures, the hydroponic cultivation device 100 is mainly composed of a cultivation bed 200 and a circulation unit 300.

The cultivation bed 200 has a structure in which a large number of planting panels 210 are arranged on the upper part of the elongated frame 202, and a spray tank 220 is formed on the lower side of the frame 202. The planting panel 210 is formed of, for example, Styrofoam, and a plurality of planting holes 212 are formed. The plant 214 to be planted has a stem portion held by a holding material 216 made of a flexible and breathable material such as urethane sponge, and is planted in the planting hole 212.

On the other hand, the spray tank 220 is composed of, for example, a vinyl chloride sheet, and water supply pipes 222 and 224 are laid on both sides of the spray tank 220 along the longitudinal direction on the bottom surface side thereof, respectively. Spray nozzles 226 are provided at intervals. In the illustrated example, the spray nozzles 226 are alternately provided on the water supply pipes 222 and 224 in the longitudinal direction of the spray tank 220. Further, a drain port 228 is provided near the center of the spray tank 220.

The mist of the aqueous solution sprayed from the spray nozzle 226 is discharged upward and sprayed onto the roots of the plant 214 planted on the planting panel 210. The mist of the aqueous solution remaining unabsorbed by the plant 214 settles in the spray tank 220 or adheres to the wall surface and falls, and is drained from the drain port 228 and collected. As described above, in this embodiment, the plant 214 is irrigated by spraying, and the irrigation by the deep flow technology that is actively immersed in the aqueous solution is not performed.

Next, the circulation unit 300 is for circulating the aqueous solution recovered from the spray tank 220 to the spray tank 220 again, and as shown in detail in FIG. 2, the pre-stage filter 310, the aqueous solution tank 320, the replenishment device 330, and the pump. It is mainly composed of 340 and the latter filter 350. Of these, the front-stage filter 310 is connected to the drain port 228 of the spray tank 220 described above by a pipe 302. An aqueous solution tank 320 is provided on the outlet side of the pre-stage filter 310 to store the aqueous solution to be sprayed. The aqueous solution tank 320 is provided with a replenishment device 330, and when the amount of the aqueous solution in the tank falls below a certain amount, water or fertilizer is appropriately supplied. The aqueous solution in the aqueous solution tank 320 is sent out to the post-stage filter 350 by the pump 340, and the outlet side of the post-stage filter 350 is connected to the water supply pipes 222 and 224 of the spray tank 220 described above by the pipe 304. There is. As the first-stage filter 310 described above, for example, a strainer, which is a net-like instrument used for removing solid components from a liquid, is used, and as the second-stage filter 350, for example, a disk type filter is used.

The aqueous solution discharged from the drain port 228 of the spray tank 220 described above is introduced into the pre-stage filter 310 from the pipe 302, where dust and root fragments are removed and returned to the aqueous solution tank 320. Then, it is sent out again by the pump 340, filtered by the post-stage filter 350 so that the spray nozzle 226 is not clogged, and provided to the spray tank 220 from the pipe 304.

By the way, the mesh size of the post-stage filter 350 is smaller than the nozzle diameter because it is conventionally intended to prevent the spray nozzle 226 from being clogged. On the other hand, in this embodiment, the eyes of the post-stage filter 350 are made finer so that the insect eggs cannot pass through. Specifically, if the mesh size (the size of the eye diameter) is 400 μm or less, the eggs can be removed, but if it is made too fine, the pump 340 is sent to secure the amount of the aqueous solution required for the growth of the plant 214. Since it may be necessary to increase the pressure, it is preferably about 200 μm to 55 μm. By doing so, not only the clogging of the spray nozzle 226 due to foreign matter is prevented, but also the insect eggs contained in the aqueous solution are removed.

Next, as the spray nozzle 226 described above, various known nozzles such as those having or not having a closer in the nozzle body may be applied. If the structure of the nozzle itself is the same, the particle size of the fog and the passing diameter of the foreign matter are almost proportional, but if the structure is different, the method of generating the fog is different, so even if the particle size of the fog is large. The foreign matter passage diameter may be small (or vice versa). FIG. 3 shows a cross section of the tip of the nozzle 226 having the same structure. The foreign matter passage diameter is the narrowest in the figure (A), the medium in the figure (B), and the largest in the figure (C). It's getting bigger. The plant 214 to be cultivated has a guideline such as how much water should be given for proper growth. For example, if the lotus root is given a little water, it will die, and if the cactus is given too much water, it will cause root rot and will not grow. If the structure of the nozzle is the same, the size of the foreign matter passing diameter of the spray nozzle 226 affects the particle size of the mist and is directly linked to the amount of water given to the plant 214. Therefore, it is desirable to set the foreign matter passage diameter to an appropriate size corresponding to the plant 214 to be cultivated.

For example, it is assumed that the state shown in FIG. 3 (B) is an appropriate foreign matter passing diameter. On the other hand, as shown in Fig. (A), if the foreign matter passage diameter is reduced with the same nozzle structure, the particle size of the sprayed mist is also reduced. On the other hand, as shown in Fig. (C), if the foreign matter passage diameter is increased with the same nozzle structure, the particle size of the fog will also increase and a large amount of water will have to flow. The manufacturing cost of the ancillary equipment will be high. As a result of conducting an experiment in consideration of these points, the foreign matter passing diameter is preferably about 0.15 mm to 0.9 mm, and in this example, the one having a foreign matter passage diameter of 0.5 mm is used.

Next, the number of spray nozzles 226 installed in the spray tank 220 may be appropriately set depending on the plant 214 to be cultivated, but in this embodiment, the planting area of the plant 214 in the planting panel 210 is 0.3 m ^2. About 1 spray nozzle 226 is installed with respect to ~ 0.6 m ² . Further, the installation interval of the spray nozzle 226 is set to 600 mm to 700 mm in this embodiment.

Next, the overall operation of this embodiment will be described. The mist of the aqueous solution sprayed from the spray nozzle 226 is discharged upward and sprayed onto the roots of the plant 214 planted on the planting panel 210. The fog remaining unabsorbed by the plant 214 settles in the spray tank 220 or adheres to the wall surface and falls, and is drained from the drain port 228. At this time, since the leaf side of the plant 214 and the spray tank 220 are separated by the planting panel 210, the invasion of the insect 500 into the spray tank 220 is reduced. Since the gap between the planting panel 210 and the plant 214 is held by the holding material 216, the insect 500 hardly invades the spray tank 220 from this portion.

In addition, the isolation also reduces the adhesion of the aqueous solution sprayed in the spray tank 220 to the leaves of the plant 214. Since the fungus propagates in the aqueous solution, the number of fungi in the plant 214 is also reduced by reducing the adhesion of the aqueous solution. Further, the isolation also prevents the intrusion of external light into the spray tank 220. For this reason, the generation of algae and the like in the spray tank 220 is also reduced, and this also suppresses the growth of bacteria.

However, on rare occasions, the insect 500 may invade the spray tank 220 and lay eggs in the aqueous solution, and the aqueous solution discharged and recovered may contain eggs. The egg 504 passes through the pre-stage filter 310 of the circulation unit 300 together with the aqueous solution, and is housed in the aqueous solution tank 320. It should be noted that the aqueous solution tank 320 constantly stores the aqueous solution, and there is little possibility that the insect 500 will enter and lay the egg 504 during the inspection work in the tank.

The aqueous solution in the aqueous solution tank 320 is sent to the subsequent filter 350 by the pump 340. As described above, the latter-stage filter 350 has a mesh value set so that the egg 504 can be removed. Therefore, the egg 504 of the insect 500 cannot pass through the subsequent filter 350, and the aqueous solution containing no egg 504 is supplied from the pipe 304 to the water supply pipes 222 and 224. Therefore, the spray nozzle 226 sprays an aqueous solution that does not contain the egg 504. At this time, not only the egg 504 of the insect 500 but also other organic substances and the like are removed. The removal of organic substances that cause the growth of bacteria also suppresses the growth of bacteria in the spray tank 220.

As described above, according to this embodiment, the following effects can be obtained.
a. Since only irrigation by spraying is performed and irrigation by deep flow is not actively performed, the occurrence of insects can be reduced because the deep flow does not lay eggs by insects.
b. Even if an insect invades the spray tank 220 or the aqueous solution tank 320 and lays eggs, it is removed from the aqueous solution by the subsequent filter 350, so that the insects hatch in the spray tank 220 is prevented.
c. Since the plant 214 and the spray tank 220 are separated by the planting panel 210, the adhesion of the aqueous solution in which the fungus propagates to the plant 214 is reduced. In addition, the invasion of external light into the spray tank 220 is prevented, or the generation of algae and the like in the spray tank 220 is reduced, and the growth of bacteria in the spray tank 220 is suppressed. .. Therefore, the number of bacteria adhering to the plant 214 is also reduced, and the total number of bacteria can be reduced.

The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the gist of the present invention. For example, the following are also included.
(1) In the above-described embodiment, the hydroponic cultivation device 100 has an elongated shape, but various shapes may be used as needed. The same applies to the water supply pipes 222, 224, the spray nozzle 226, and the drain port 228, and the pipe shape and the number of installations may be appropriately set as needed.
(2) In the above embodiment, two filters, a front stage and a rear stage, are provided, but the number of filters may be increased or decreased as necessary, and it is known that a coarse filter and a fine filter are combined to form a multi-stage type. Method may be applied.

(3) The aqueous solution to be sprayed depends on the plant 214. For example, in the case of lettuce, a mixture of nitrogen, potassium and calcium is used. Specifically, Farm Ace Nos. 1, 2, and 3 manufactured by Kaneko Seed Co., Ltd. are used. It can be just water.
(4) In the above embodiment, spawning in an aqueous solution due to the invasion of the insect 500 into the spray tank 220 or the aqueous solution tank 320 is shown as a typical example, but the insect 500 may invade from other routes. However, by providing the post-stage filter 350 at a position close to the spray nozzle 226 in the flow path of the aqueous solution, it is possible to remove the eggs laid by the insect 500 invading from another route.
(5) In the present invention, only the aqueous solution is sprayed, and the roots of the plant 214 are not intentionally or positively immersed in the aqueous solution, but the sprayed aqueous solution accumulates in the spray tank 220 to some extent. The roots of plant 214 may be soaked in. Even in such a case, it is included in "only spraying the aqueous solution" in the present invention, and it is intended that irrigation with a deliberate and aggressive deep flow technique is not performed.

(6) In the above embodiment has been installed planting area 0.18 m ² ～0.42M spray nozzle 226 for each ^two plants 214 in planting panel 210 at a ratio of about 1, depending on the plant 214 to grow It may be increased or decreased as appropriate. However, even if the number of spray nozzles 226 installed is increased more than necessary, the cost will increase, and conversely, if the number of spray nozzles 226 installed is reduced, sufficient spraying cannot be performed. From this point of view, the proportion of 1 or so per planting area 0.08m ² ~1.0m ² are considered to be preferred, in the above embodiment, the planting area 0.18m ² ~0.42m ² It has one nozzle.

(7) In the above embodiment, as shown in FIG. 1 (A), the spray nozzles 226 were alternately arranged on both sides in the longitudinal direction of the spray tank 220, but as shown in FIG. 4 (A), one of them was arranged. The spray nozzle 226 may be arranged only on the side. Further, it is not always necessary to arrange them at equal intervals, and as shown in FIG. 6B, they may be arranged two by two and the spraying direction may be set appropriately.
(8) In the above embodiment, the water supply pipes 222 and 224 are arranged on both sides of the spray tank 220, but the water supply pipe may be installed in the center of the spray tank 220, and various types such as S-shaped and crank-shaped. It may be arranged. The same applies to the spray tank 220.

According to the present invention, since only the solution is sprayed on the roots of the plant and the eggs of the insects are removed, the outbreak of insects can be satisfactorily reduced and the adhesion of bacteria is also reduced. It is suitable for hydroponic cultivation of vegetables and the like.

100: Hydroponic cultivation device 200: Cultivation bed 202: Frame 210: Planting panel 212: Planting hole 214: Plant 216: Holding material 220: Spray tank 222, 224: Water supply pipe 226: Spray nozzle 228: Drainage port 300 : Circulation unit 302: Piping 304: Piping 310: Pre-stage filter 320: Aqueous tank 330: Replenishment device 340: Pump 350: Post-stage filter 500: Insect 504: Egg

Claims (9)

It is a hydroponic cultivation device that irrigates the plants planted in the cultivation bed and cultivates them.
A spray tank is provided on the root side of the plant in the cultivation bed, and the plant is provided with a spray tank.
In this spray tank, a spraying means for spraying an aqueous solution on the roots of the plant,
A circulation means that collects the aqueous solution in the spray tank and supplies it to the spray means again.
Is equipped with
A hydroponic cultivation apparatus characterized in that the plant is cultivated by only spraying an aqueous solution by the spraying means. The hydroponic cultivation apparatus according to claim 1, wherein the circulation means is provided with a filter means for removing insect eggs contained in an aqueous solution. The hydroponic cultivation apparatus according to claim 2, wherein the filter means is arranged at a position closest to the spraying means in the circulation path of the circulation means. The hydroponic cultivation apparatus according to claim 3, wherein the mesh size of the filter means is 400 μm or less, preferably 200 μm to 55 μm. Said spray means, the planting area 0.08m ² ~1.0m ² 1 or so per the plant, that preferably the installed at a ratio of 1 or so per planting area 0.18m ² ~0.42m ² The hydroponic cultivation apparatus according to any one of claims 1 to 4. The hydroponic cultivation apparatus according to any one of claims 1 to 5, wherein the foreign matter passing diameter in the spraying means is set to about 0.15 mm to 0.9 mm, preferably about 0.5 mm. A hydroponic filter used for cultivating the plant by spraying an aqueous solution in a spray tank provided on the root side of the plant planted in the cultivation bed.
A filter for hydroponics, which has a function of removing insect eggs in the collected aqueous solution when the aqueous solution in the spray tank is collected and sprayed again in the spray tank. It is a hydroponic cultivation method in which plants are irrigated and cultivated.
A spraying step of spraying an aqueous solution onto the roots of the plant,
A circulation process in which the sprayed aqueous solution is collected and sprayed again,
Including
A hydroponic cultivation method characterized in that the plant is cultivated by spraying only the aqueous solution in the spraying step. The hydroponic cultivation method according to claim 8, further comprising an egg removing step of removing eggs in an aqueous solution.

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