WO2017169426A1 - 海水を用いた水耕栽培システム、及び播種育苗用の栽培システム - Google Patents
海水を用いた水耕栽培システム、及び播種育苗用の栽培システム Download PDFInfo
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- WO2017169426A1 WO2017169426A1 PCT/JP2017/007413 JP2017007413W WO2017169426A1 WO 2017169426 A1 WO2017169426 A1 WO 2017169426A1 JP 2017007413 W JP2017007413 W JP 2017007413W WO 2017169426 A1 WO2017169426 A1 WO 2017169426A1
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- seawater
- salt
- water
- cultivation system
- tolerant
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
- A01G31/00—Soilless cultivation, e.g. hydroponics
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
- A01G31/00—Soilless cultivation, e.g. hydroponics
- A01G31/02—Special apparatus therefor
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/58—Treatment of water, waste water, or sewage by removing specified dissolved compounds
- C02F1/62—Heavy metal compounds
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2101/00—Nature of the contaminant
- C02F2101/10—Inorganic compounds
- C02F2101/20—Heavy metals or heavy metal compounds
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2103/00—Nature of the water, waste water, sewage or sludge to be treated
- C02F2103/08—Seawater, e.g. for desalination
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2209/00—Controlling or monitoring parameters in water treatment
- C02F2209/10—Solids, e.g. total solids [TS], total suspended solids [TSS] or volatile solids [VS]
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2303/00—Specific treatment goals
- C02F2303/04—Disinfection
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P60/00—Technologies relating to agriculture, livestock or agroalimentary industries
- Y02P60/20—Reduction of greenhouse gas [GHG] emissions in agriculture, e.g. CO2
- Y02P60/21—Dinitrogen oxide [N2O], e.g. using aquaponics, hydroponics or efficiency measures
Definitions
- the present invention relates to a hydroponics system for hydroponically cultivating salt-tolerant plants using seawater and a cultivation system for sowing seedlings.
- This application claims priority based on Japanese Patent Application No. 2016-073439 filed in Japan on March 31, 2016 and Japanese Patent Application No. 2016-073438 filed in Japan on March 31, 2016. The contents are incorporated herein.
- plant factories that grow plants such as edible vegetables in indoor facilities.
- a plant factory in an environment maintained at a temperature and humidity suitable for plant growth, seeding in a cultivation container, feeding of nutrients from the medium in the container, and light irradiation from a light source such as a fluorescent lamp or LED Germination, greening, seedling, cultivation, and harvesting are each performed.
- Vegetables cultivated in plant factories can be supplied in a stable manner that is not affected by the weather, can be cultivated with optimized culture materials, have high nutritional value, and can be grown without pesticides due to the absence of insect damage. It has excellent points such as being.
- the growing method of the plant to grow up to a seedling with fresh water and to grow with salt water (seawater) after that is known.
- a salt-resistant plant such as a mangrove is used for the rootstock. It is known that enables cultivation in a saltwater environment.
- Patent Document 1 describes a gene that simultaneously imparts disease resistance, drought resistance, salt resistance, improved photosynthetic efficiency, and increased number of tillers.
- Patent Document 1 For a grown product obtained as a food plant, a method that does not use the method by genetic recombination as shown in Patent Document 1 is required. Moreover, when cultivating using salt water, it is known that rooting is difficult in a medium having a concentration of seawater. That is, since the process of germination and rooting is very sensitive to salt concentration, a specific structure of a nursery bed for seawater raising that imparts salt tolerance at the seawater level to a plant has not been realized. Therefore, there has been a demand for a structure capable of effectively cultivating a plant using salt water without a low cost and a complicated structure.
- the present invention has been made in view of the above-described problems, and can achieve seawater hydroponics using seawater and enables hydroponic cultivation from which unnecessary substances such as bacteria and garbage are removed. It aims at providing the hydroponic cultivation system using.
- the present invention has been made in view of the above-described problems, and provides a cultivation system for sowing seedlings and seedlings capable of realizing excellent cultivation using salt water with a simple structure at a low cost. Objective.
- a hydroponic cultivation system using seawater is a hydroponic cultivation system using seawater for hydroponic cultivation of salt-tolerant plants using seawater, wherein the salt concentration and the amount of bacteria , And a water supply pump that pumps seawater whose waste is below a certain standard from the sea, a water tank that stores the seawater pumped by the water pump, and a salt-tolerant plant to be cultivated, and bacteria in seawater taken from the sea, and And a removal unit for removing unnecessary substances, wherein seawater from which the bacteria and the unnecessary substances are removed by the removal unit is sent to the water tank.
- seawater whose salt concentration, amount of bacteria, and unwanted substances are below a certain standard is pumped from the sea with a feed pump, and the bacteria and unwanted substances in the seawater are removed by the removal unit, and then supplied to the water tank for storage.
- the removal unit removes substances that inhibit the growth of the salt-tolerant plants due to dissolved oxygen and heavy metals, and substances that cause harm to humans. It is good also as having the function to perform.
- the removal part removes substances that inhibit the growth of the salt-tolerant plants due to dissolved oxygen and heavy metals and substances that cause harm to humans, so that salt-tolerant plants can be cultivated more reliably by seawater. .
- a monitoring unit may be provided.
- the monitoring unit can stabilize the seawater in the aquarium and take cultivation Yield can be improved. Furthermore, it becomes possible to avoid necrosis of a salt-tolerant plant by making it the structure which can exchange a part or all of seawater, and can aim at the improvement of productivity.
- a part or all of the seawater may be provided to be exchangeable.
- a seawater temperature adjustment unit for adjusting a temperature of the seawater supplied to the water tank. It may be.
- the temperature of the seawater supplied to the water tank can be cooled to the seawater temperature by the seawater temperature control unit and supplied to the water tank, and the seawater temperature in the water tank can be kept constant.
- a dissolved oxygen supply unit that supplies dissolved oxygen to the seawater supplied to the water tank is provided. It may be done.
- a cultivation system for sowing seedlings is a cultivation system for sowing seedlings for growing salt-tolerant seedlings using a salt-tolerant agent, and the salt-tolerant seedlings are germinated with fresh water.
- a salt diffusion inhibiting part is provided between the fresh water medium part and the salt water part.
- the salt-tolerant seedling can be germinated and rooted in a state where the salt water part and the fresh water medium part are separated by the salt diffusion inhibiting part, and after germination and rooting, the roots rooted in the salt water part are It can be grown in salt water.
- salt-tolerant seedlings can be grown only with fresh water isolated from salt water, and at a stage where the roots grow to some extent and the salt promotes the growth. It becomes possible to grow with salt water in the salt water section. Therefore, productivity can be improved without causing salt-resistant seedlings to die.
- diffusion inhibition part which consists of simple structures, such as providing a clearance gap between a freshwater culture
- the fresh water medium part is provided with a support that can be attached to and detached from the salt water part, and the support is made from salt water in the salt water part. May also be located above.
- the support body provided in the fresh water medium part is detachably provided at a position above the salt water part, the next cultivation can be performed by appropriately replacing the support body.
- a support is provided for each salt-tolerant seedling, it is possible to exchange the support for the salt water part in accordance with the growth state of each salt-tolerant seedling.
- a support body is provided for a plurality of salt-tolerant seedlings, a plurality of salt-tolerant seedlings can be replaced at the same time by exchanging only one support body with respect to the salt water section, thereby improving work efficiency Can be planned.
- the salt tolerance imparting agent may be imparted to at least one of fresh water in the fresh water medium part and salt water in the salt water part. Good.
- the salt-tolerant agent can be easily attached to the salt-tolerant seedling by a simple configuration in which a salt-tolerant agent is imparted to the fresh water contained in the fresh water medium part or the salt water of the salt water part.
- the salt tolerance-imparting agent may be a microorganism.
- the salt-tolerant seedling can be grown.
- the salt diffusion inhibiting part is formed between the fresh water medium part and the salt water of the salt water part. Clearance may be used.
- the clearance may be 1 mm or more, or 10 cm to 30 cm.
- the salt water can be prevented from diffusing and adhering to the fresh water medium part and the seed of the salt-resistant seedling before germination and rooting.
- the timing at which the roots of the salt-tolerant seedlings adhere to the salt water or the salt-tolerant agent can be shifted, so that the speed of growing the salt-tolerant seedlings can be adjusted.
- the salt diffusion inhibiting part is provided between the fresh water medium part and the salt water of the salt water part. It may be a film-like semipermeable membrane.
- the fresh water medium part and the salt water are separated by the semipermeable membrane, it is possible to suppress the diffusion and attachment of the salt water to the fresh water medium part and the seed of the salt-resistant seedling before germination and rooting. it can.
- the timing at which the roots of the salt-tolerant seedlings adhere to the salt water or salt-tolerant agent can be shifted, so the speed of salt-tolerant seedling growth can be adjusted.
- the fresh water medium part may have a semi-solid medium that inhibits salt intrusion.
- the salt water part may have a semi-solid medium that inhibits salt diffusion.
- the diffusion of salt to the surroundings can be suppressed by adding salt water to the semi-solid medium that inhibits salt diffusion.
- seawater hydroponic cultivation can be realized using seawater, and hydroponic cultivation from which unnecessary substances such as bacteria and garbage are removed It becomes possible.
- FIG. 1 is a diagram schematically showing a hydroponic cultivation system using seawater according to the first embodiment of the present invention.
- FIG. 2 is a perspective view schematically showing a cultivation system for sowing and raising seedlings according to a second embodiment of the present invention.
- FIG. 3A is a diagram showing a cultivation process using the cultivation system shown in FIG. 2.
- FIG. 3B is a diagram showing a cultivation process using the cultivation system shown in FIG. 2.
- FIG. 3C is a diagram showing a cultivation process using the cultivation system shown in FIG. 2.
- FIG. 4 is a side sectional view schematically showing a cultivation system for sowing seedlings according to the third embodiment.
- FIG. 5 is a perspective view of the holder of the fresh water medium part in the cultivation system shown in FIG. FIG.
- FIG. 6A is a diagram showing a cultivation process using the cultivation system shown in FIG.
- FIG. 6B is a diagram illustrating a cultivation process using the cultivation system illustrated in FIG. 4.
- FIG. 6C is a diagram illustrating a cultivation process using the cultivation system illustrated in FIG. 4.
- FIG. 6D is a diagram illustrating a cultivation process using the cultivation system illustrated in FIG. 4.
- FIG. 7 is a side sectional view schematically showing a cultivation system for sowing seedlings according to the fourth embodiment.
- FIG. 8A is a diagram showing a cultivation process using the cultivation system for sowing seedlings according to the fifth embodiment.
- FIG. 8B is a diagram illustrating a cultivation process using the cultivation system for sowing seedlings according to the fourth embodiment.
- FIG. 8C is a diagram showing a cultivation process using the cultivation system for sowing seedlings according to the fourth embodiment.
- FIG. 9A is a side sectional view showing a cultivation system for sowing seedlings according to a sixth embodiment, and shows a state of a freshwater cultivation period;
- FIG. 9B is a side sectional view showing a cultivation system for sowing seedlings according to the fifth embodiment, and is a view showing a state of a seawater cultivation period.
- FIG. 10 is a sectional side view showing a cultivation system for sowing seedlings according to another embodiment.
- FIG. 11 is a schematic diagram showing a cultivation system for sowing seedlings according to another embodiment.
- FIG. 12 is a schematic diagram showing a cultivation system for sowing seedlings according to another embodiment.
- the hydroponic cultivation system 1 is for hydroponic cultivation of a salt-tolerant plant P using seawater W1 taken from the sea S.
- the hydroponic cultivation system 1 stores a water supply pump 21 that pumps seawater W1 from the sea S, a water tank 30 that stores the seawater W1 pumped by the water supply pump 21, a salt-tolerant plant P that is cultivated, and seawater in the water tank 30.
- a circulation pump 41 that circulates W1 through drainage or a circulation system 60 described later.
- the water supply side system including the water supply pump 21 between the sea S and the water tank 30 is referred to as the water supply system 20, and the water discharge side system between the water tank 30 and the sea S is drained. It is called system 40.
- the some water tank 30, 30, ... is provided and the cultivation system
- FIG. 1 only one system of reference numeral 3A is shown in detail, and the other systems (reference numerals 3B and 3C) are indicated by broken lines.
- the water supply system 20 includes a pair of the water supply pumps 21 (21A, 21B), a seawater supply tank 22 for temporarily storing seawater W1 pumped from the sea S by the water supply pumps 21A, 21B, and fresh water W2 mixed with the seawater W1. And a fresh water supply tank 23 for stabilizing the water quality, and a water supply pump 24 provided in a water supply pipe 25 connecting the sea water supply tank 22 and the water tank 30.
- the water supply pumps 21A and 21B are arranged in parallel, and water supply valves 261 and 262 are provided in the water supply pipes 26A and 26B respectively connected to the sea S. By appropriately opening and closing these water supply valves 261 and 262, a desired amount of seawater W1 is stored in the seawater supply tank 22. Seawater W ⁇ b> 1 supplied by the pair of water supply pumps 21 ⁇ / b> A and 21 ⁇ / b> B passes through the filter 27 (removal unit) and is sent to the seawater supply tank 22.
- the water intake by the water supply pumps 21A and 21B is preferably, for example, seawater W1 of 5 cm or more excluding the surface from the sea surface.
- the filter 27 removes bacteria such as plankton in the seawater W1 taken by the water supply pump 21 and unnecessary materials such as dust.
- the filter 27 preferably has a function of removing substances that inhibit the growth of salt-tolerant plants by dissolved oxygen and heavy metals and substances that are harmful to humans. Then, the seawater W1 from which the bacteria and unnecessary substances as described above are removed by the filter 27 is stored in the seawater supply tank 22 and further supplied to the water tank 30.
- the monitoring part water tank monitoring part mentioned later which detects the property of seawater W1 before being supplied to the water tank 30, and the seawater W1 after being supplied to the water tank 30 70).
- a water supply valve 241 is provided in a water supply pipe 25 (25a) between the seawater water supply tank 22 and the water supply pump 24. By appropriately opening and closing the water supply valve 241, the seawater W1 stored in the seawater supply tank 22 can be supplied into the water tank 30.
- the fresh water pipe 231 connected to the fresh water supply tank 23 is connected between the water feed valve 241 and the water feed pump 24 of the water feed pipe 25 (25a).
- a fresh water supply pump 232 is provided in the fresh water pipe 231. Specifically, after evaluating the quality of the seawater W1 by monitoring substances that are harmful to the cultivation of the salt-tolerant plant P, the freshwater supply pump 232 is operated, and the freshwater W2 is supplied to the seawater W1 in the water supply pipe 25. It becomes the structure which can stabilize water quality by mixing.
- a growth promoting material supply system 50 is connected to a water supply pipe 25 (25b) between the water pump 24 and the water tank 30.
- the growth promoting material supply system 50 is provided with a microorganism input unit 51 and a fertilizer input unit 52.
- a microorganism input unit 51 and the fertilizer input unit 52 an appropriate amount of microorganisms and fertilizer is added based on the detected values of the microorganism concentration and fertilizer concentration of the seawater W stored in the water tank 30 or the flow velocity value of the seawater W1 in the water tank 30. It is thrown into the seawater W1 in the water supply pipe 25 (25b).
- the microorganism input unit 51 and the fertilizer input unit 52 are provided with input / output valves 511 and 521, respectively.
- microorganisms disclosed in Journal of Plant Interactions, Volume 9, Issue 1, 2014 can be applied as microorganisms to be introduced into the seawater W1.
- fertilizers to be introduced into seawater W1 for example, liquid fertilizer Hyponex (manufactured by Hyponex Japan), solid fertilizer vegetable fertilizer (manufactured by Takii Tanaesha), organic fertilizer containing organic fertilizer with bone meal (Asahi Industries) Etc.).
- the water tank 30 is disposed on a leakage prevention sheet 32 that prevents the stored seawater W1 from leaking out to the surroundings.
- the aquarium 30 is provided with a semi-solid medium 31 that is arranged in the state of a seedling or rooted seedling of the salt-tolerant plant P, and is detachably arranged with respect to the upper edge of the aquarium of the aquarium 30.
- a semi-solid medium 31 for example, a porous sponge material is fitted in a rectangular cylindrical support formed of a member such as plastic, ceramic, foamed resin, or wood.
- the sponge material is made of a material that can support the salt-tolerant plant P until it germinates and roots from the seed.
- a synthetic sponge formed by foaming a synthetic resin such as polyurethane or a natural sponge processed from a biological sponge is used. be able to.
- the water tank 30 is provided with a water tank monitoring unit 70 (monitoring unit) that detects the properties of the seawater W1 in the water tank 30.
- the water tank monitoring unit 70 includes a water level detection unit 71, a fertilizer detection unit 72, a microorganism detection unit 73, and a salt concentration detection unit 74.
- the water level detection unit 71 measures the water level of the seawater W1 in the water tank 30.
- the amount of water in the water tank 30 is managed from the water level measured by the water level detection unit 71, and control is performed to lower the water level, for example, when microorganisms are charged.
- the fertilizer detection part 72 measures the fertilizer density
- the amount of fertilizer input by the fertilizer input unit 52 described above is controlled from the fertilizer concentration obtained based on the fertilizer concentration and flow rate measured by the fertilizer detection unit 72.
- the microorganism detection unit 73 measures the microorganism concentration of the seawater W1 in the water tank 30, or measures the flow rate of the seawater W1. From the microorganism concentration obtained based on the microorganism concentration and flow rate measured by the microorganism detection unit 73, the amount of microorganisms input by the microorganism input unit 51 is controlled.
- the salt concentration detection unit 74 measures the salt concentration of the seawater W1 in the water tank 30. When the salt concentration measured by the salt concentration detector 74 is higher than a predetermined level, for example, control is performed to replace part or all of the seawater W1 in the aquarium 30, or freshwater W2 is supplied from the freshwater supply tank 23. The supply is controlled to adjust the salt concentration.
- the drainage system 40 includes the circulation pump 41 disposed near the downstream of the water tank 30, a drainage tank 42 for temporarily storing the seawater W1 in the water tank 30 by the circulation pump 41 and draining it into the sea S, and a drainage tank 42. And a wastewater treatment unit 43 that performs wastewater treatment on the seawater W1 stored inside.
- An intermediate drain pipe 45 branched from the water supply pipe 25 (25b) is connected to an intermediate portion of the drain pipe 44 connecting the circulation pump 41 and the drain tank 42.
- the seawater W1 outside the applicable range is sent to the drainage tank 42 through the intermediate drainage pipe 45. Yes.
- the sea water W1 in the tank can be discharged into the sea S by natural flow. In addition, you may make it drain to the sea S using the drainage pump which is not illustrated.
- the circulation system 60 described above is a system that circulates the seawater W1 in the water tank 30 and is branched at a position closer to the downstream side than the circulation pump 41, and the water supply pipe 25 (between the water supply pump 24 and the water tank 30 ( 25b).
- the circulation system 60 includes a micro / nano bubble generator 61 (dissolved oxygen supply unit) that supplies dissolved oxygen to the seawater W1 discharged by the circulation pump 41, and the temperature of the seawater W1 discharged by the circulation pump 41 is cooled to the seawater temperature.
- a cooling device 62 (seawater temperature adjusting unit).
- the micro-nano bubble generator 61 has a function of purifying the seawater W1 and promoting the growth of the salt-tolerant plant P by securing dissolved oxygen to the seawater W1 flowing into the circulation system 60 from the circulation pump 41. ing.
- the cooling device 62 is provided on the downstream side of the micro / nano bubble generator 61, and has a function of cooling the seawater W1 in which dissolved oxygen is secured to the seawater temperature. As described above, in the hydroponic cultivation system 1, by providing the circulation system 60 with the micro / nano bubble generator 61 and the cooling device 62, the seawater temperature and the dissolved oxygen concentration in the water tank 30 can be kept constant.
- the hydroponic cultivation method of the salt tolerant plant P using the hydroponic cultivation system 1 mentioned above is demonstrated using FIG.
- the seawater W1 is pumped from the sea S by the water supply pumps 21A and 21B, passes through the filter 27, and is stored in the seawater water supply tank 22. At this time, bacteria and unnecessary substances in the seawater W1 are removed by the filter 27.
- fresh water W2 is stored in the fresh water supply tank 23 from a fresh water source (river or water supply) (not shown).
- the method of storing fresh water W2 in the water tank 30 is employ
- the fresh water W2 is fed from the fresh water feed tank 23 to the water tank 30 by the water feed pump 24 without feeding the sea water W1 from 22. Then, for example, 3 to 7 days after the root of the salt-tolerant plant P reaches the surface of the fresh water W2 in the water tank 30, the seawater W1 is replaced.
- the fresh water W2 in the water tank 30 is sent to the drainage tank 42 by the circulation pump 41, and the freshwater W2 is drained by the drainage treatment unit 43 and then drained into the sea S.
- the water supply passage by the water supply pump 24 is switched from the freshwater supply tank 23 to the seawater supply tank 22 in which the seawater W1 is stored, and the seawater W1 is supplied to the water tank 30 for storage.
- the water level of the seawater W1 is set to be lower than that in the steady state in order to increase the chance of contact with microorganisms.
- the circulation pump 41 is operated to circulate the seawater W1 in the water tank 30 by circulating it through the circulation system 60 so that the seawater W1 in the water tank 30 has a predetermined flow rate.
- the seawater W1 circulated in the circulation system 60 passes through the micro-nano bubble generator 61 and the cooling device 62, the seawater temperature and the dissolved oxygen concentration in the water tank 30 are kept constant.
- the water level, fertilizer concentration, microorganism concentration, and salt concentration of the seawater W1 in the water tank 30 are detected by the water tank monitoring unit 70, and control based on the detected value is performed. For example, when the fertilizer concentration and the microorganism concentration in the seawater W1 are insufficient, an appropriate amount of microorganisms and fertilizer according to the detected value are input by the microorganism input unit 51 and the fertilizer input unit 52 of the growth promoting material supply system 50. Will be. Further, when the salt concentration is high, it is possible to mix an appropriate amount of fresh water W2 into the water tank 30, or to replace all the seawater W1 in the water tank 30.
- the seawater W1 in the aquarium 30 is replaced.
- the seawater W1 in the water tank 30 at this time is sent to the drainage tank 42 by the circulation pump 41 and drained into the sea S after being drained by the drainage treatment unit 43.
- seawater W1 whose salt concentration, amount of bacteria, and unnecessary substances are below a certain standard is pumped from the sea S by a feed water pump 21, and the bacteria and unnecessary substances in the seawater W1 are filtered. After removing at 27, the water can be supplied to the water tank 30 and stored therein, whereby the salt-tolerant plant P can be hydroponically cultivated in the water tank 30.
- the hydroponic cultivation system 1 using the seawater W1 taken from the sea S a large-scale and highly productive seawater hydroponic cultivation place can be realized.
- the filter 27 removes substances that inhibit the growth of the salt-tolerant plant P due to dissolved oxygen and heavy metals and substances that are harmful to humans, so that the salt-tolerant plant P can be more reliably grown by the seawater W1. Can be done.
- the aquarium monitoring unit 70 detects and monitors the properties of the seawater W1 before and after the supply to the aquarium 30, such as the salt concentration, fertilizer, and the amount of microorganisms, thereby stabilizing the seawater W1 in the aquarium 30. Therefore, the yield concerning cultivation can be improved. Furthermore, it becomes possible to avoid necrosis of the salt-tolerant plant P by setting it as the structure which can exchange a part or all of seawater W1, and can aim at the improvement of productivity.
- the hydroponic cultivation system 1 of the present embodiment even when bacteria, unwanted substances, plant-inhibiting substances are mixed after the seawater W1 is stored in the water tank 30, or when the salt concentration becomes high, the water tank 30. Some or all of the seawater W1 can be replaced. Furthermore, by configuring the drainage system 40 that drains the seawater W1 in the water tank 30 to the sea S, part or all of the seawater W1 in the water tank 30 can be replaced with a simple structure.
- seawater hydroponic cultivation can be realized using the seawater W1, and hydroponic cultivation in which unnecessary substances such as bacteria and garbage are removed. It becomes possible.
- the cultivation system 101 for sowing seedlings grows salt-tolerant seedlings 102 using a salt-tolerant agent, and includes seawater W1 ( The salt-tolerant seedling 102 is cultivated using salt water.
- the cultivation system 101 immerses and grows the root 102a of the rooted salt-tolerant seedling 102 in the seawater W1 and the freshwater medium part 110 provided in the freshwater medium region P1 for germinating and rooting the salt-tolerant seedling 102 with the freshwater W2.
- a seawater portion 120 (salt water portion) provided in the seawater culture medium region P2.
- the period from seeding to germination / rooting of the salt-tolerant seedling 102 as shown in FIG. 3A with fresh water W2 is referred to as a freshwater cultivation period
- the root 102a of the salt-tolerant seedling 102 as shown in FIGS. 3B and 3C is seawater.
- the period for growing by W1 is called seawater cultivation period.
- the clearance 103 salt diffusion inhibition part is formed between the freshwater culture medium part 110 and the seawater part 120 in the freshwater cultivation period.
- the freshwater medium part 110 is detachably attached to the seawater part 120, and is, for example, a rectangular cylindrical support formed of a member such as plastic, ceramic, foamed resin, or wood.
- a cylinder 111 (support) is provided.
- a porous sponge material 112 (semi-solid medium) capable of containing fresh water W2 is fitted.
- the size of the support cylinder 111 is set to such a size that one salt-tolerant seedling 102 can be grown to a desired size.
- the sponge material 112 is made of a material that contains fresh water W2 in the support cylinder 111 and can support the salt-resistant seedling 102 until it germinates and roots from the seed 102c.
- a synthetic sponge obtained by foaming a synthetic resin such as polyurethane, Natural sponges made from processed sponges can be used.
- the seawater W1 is stored in a water tank or the like (not shown), and the upper surface of the seawater W1 is located below the plurality of freshwater medium portions 110 with an interval (the clearance 103).
- the clearance 103 at this time is set to 1 mm or more, or 10 cm to 30 cm. That is, if the clearance 103 is 1 mm or more, an effect of preventing oxygen deficiency is obtained, and the effect of preventing oxygen deficiency is further enhanced by setting the clearance 103 to 30 cm or less.
- FIG. 3A shows a state where the seed 102c of the salt-tolerant seedling 102 is sown on the sponge material 112, that is, a state before germination and rooting.
- FIG. 3B shows a state in which the salt-tolerant seedling 102 has germinated and rooted in the sponge material 112.
- FIG. 3C shows a state in which the root 102 a of the salt-tolerant seedling 102 extends below the sponge material 112 and is immersed in the seawater W ⁇ b> 1 of the seawater part 120.
- the fresh water medium part 110 and the seawater part 120 are each provided with a microorganism 104 (a salt-tolerant agent). Specifically, in the fresh water medium part 110, the microorganism 104 is imparted to the fresh water W2 contained in the sponge material 112.
- the seawater part 120 is provided in a state where the microorganism 104 is directly input to the seawater W1.
- the microorganism 104 for example, a microorganism disclosed in Journal of Plant Interactions, Volume 9, Issue 1, 2014 can be applied.
- the seed 102c of the salt-tolerant seedling 102 is sown in the fresh water W2 included in the sponge material 112 of the fresh water medium section 110.
- the seed 102 c at this time may be placed only on the upper surface of the sponge material 112 or may be disposed so as to be embedded in the surface layer portion of the sponge material 112.
- the seed 102c germinates and roots in contact with the fresh water W2 contained in the sponge material 112, as shown in FIG. 3B.
- the microorganism 104 is applied to the sponge material 112 at an appropriate timing. Thereby, the buds 102b and the roots 102a can be grown by the microorganisms 104 adhering to the roots 102a extending in the sponge material 112.
- the root 102a extending downward from the fresh water medium part 110 is immersed in the seawater W1 of the seawater part 120 to which the microorganisms 104 have been applied in advance via the clearance 103, and is salt-resistant.
- a seedling 102 is grown.
- the bud 102b and the root 102a are also grown.
- the salt-tolerant seedling 102 can be germinated and rooted in a state where the seawater portion 120 and the freshwater medium portion 110 are separated by the clearance 103, and further, after the germination and rooting, the seawater portion
- the root 102a rooted at 120 can be grown by immersing in the seawater W1.
- the salt concentration of the seawater part 120 can be set to 1% or less, preferably less than 0.1%, more preferably about 0%, and is set to conditions suitable for germination and rooting. Therefore, germination and rooting can be suitably performed.
- the salt-tolerant seedling 102 can be grown only with fresh water W2 isolated from the seawater W1, and the roots grow to some extent to grow the salt. It is possible to grow with the seawater W1 in the seawater section 120 at the stage of promoting the water. Therefore, productivity can be improved without causing the salt-tolerant seedling 102 to die. Moreover, in this Embodiment, since it becomes a simple structure of providing the clearance 103 between the freshwater culture medium part 110 and the seawater part 120, the cost concerning an installation can be held down.
- the support cylinder 111 provided in the freshwater medium section 110 is detachably provided at a position above the seawater section 120, the next cultivation can be performed by appropriately replacing the support cylinder 111.
- Productivity can be improved. That is, when the support tube 111 is provided for each sponge material 112 as in the present embodiment, the support tube 111 can be replaced with respect to the seawater portion 120 in accordance with the growth state of each salt-resistant seedling 102. It becomes possible.
- the microorganism 104 can be easily attached to the salt-tolerant seedling 102 with a simple configuration in which the microorganism 104 is applied to the freshwater W2 included in the freshwater medium section 110 or the seawater W1 of the seawater section 120. .
- the salt-tolerant seedling 102 can be grown.
- the seawater diffuses and adheres to the freshwater medium part 110 and the seed 102c of the salt-tolerant seedling 102 before germination and rooting. Can be suppressed.
- the size (height) of the clearance 103 the timing at which the root 102a of the salt-tolerant seedling 102 adheres to the seawater W1 or the microorganism 104 can be shifted, so the speed of the salt-tolerant seedling 102 growing can be adjusted. Can do.
- the clearance 103 in the range of 1 mm or more, or 10 cm or more and 30 cm or less, it is possible to more reliably suppress the diffusion of salt water to the fresh water medium part 110 and the seed 102c.
- the cultivation system for sowing seedlings according to the present embodiment can realize excellent cultivation using the seawater W1 with a simple structure at a low cost.
- a cultivation system 101A according to the third embodiment shown in FIG. 4 is provided with a fresh water medium part 110A having a holder 115 (support) in which a plurality of sponge materials 112 are arranged.
- the holder 115 is a plate-like member made of a lightweight and water-floating material such as foamed polystyrene, plastic, wood, gypsum board, etc., and has a thickness at a predetermined interval along the surface direction.
- a plurality of through holes 115a penetrating in the direction are formed.
- the plurality of sponge materials 112 are fitted into the plurality of through holes 115a.
- the through holes 115a are not limited to being arranged at regular intervals in the vertical and horizontal directions as shown in FIG. 4, and can be appropriately arranged according to the type of salt-tolerant seedling 102 to be cultivated.
- the fresh water medium section 110A of the present embodiment is provided with a fresh water tank 116 in which fresh water W2 is stored so that the holder 115 can be submerged.
- the seawater section 120A is provided with a seawater tank 121 that is provided separately from the freshwater tank 116 and stores the seawater W1.
- a frame member 122 is connected to the seawater tank 121, and a holding portion 123 that holds the holder 115 in a detachable manner is provided on the frame member 122.
- the holding part 123 is formed in an L-shape, and is arranged all around or partially along the circumferential direction of the sea water tank 121, and is configured to support the holder 115 from below.
- maintenance part 123 is set to the upper position which opened the predetermined space
- FIG. 6A After seeding the seed 102c of the salt-tolerant seedling 102 on each of the plurality of sponge materials 112 of the holder 115 in the fresh water medium region P1, the holder 115 is stored in the fresh water W2 stored in the fresh water tank 116. Soak in water. Thereafter, as shown in FIGS. 6B and 6C, the microorganism 104 is applied to the sponge material 112 at an appropriate timing when the salt-tolerant seedling 102 germinates and roots. Subsequently, as shown in FIG.
- the holder 115 is taken out from the freshwater water tank 116 and held in the holding portion 123 of the seawater water tank 121 with the root 102 a of the salt-tolerant seedling 102 extending downward from the holder 115. Accordingly, the holder 115 is disposed above the seawater W1 with the clearance 103.
- the seawater W1 is provided with microorganisms 104 at an appropriate timing. The timing at which the microorganism 104 is applied may be either before or after the holder 115 is placed on the holding unit 123. Thereby, the tip of the root 102a of the salt-tolerant seedling 102 grown to a predetermined length by the fresh water W2 in the seawater medium region P2 is immersed in the seawater W1.
- a plurality of salt-tolerant can be obtained by replacing only one holder 115 with the seawater part 120.
- the seedling 2 can be exchanged simultaneously, and work efficiency can be improved.
- the cultivation system 101B according to the fourth embodiment shown in FIG. 7 has a film-like semipermeable membrane 105 (on the boundary portion between the holder 115 and the seawater W1 as in the second embodiment described above.
- the salt diffusion inhibiting part is detachably arranged.
- the semipermeable membrane 105 is disposed so as to cover the lower surface 115 b of the holder 115.
- As the semipermeable membrane 105 a material that does not allow salt of seawater W1 to permeate toward the holder 115 near the fresh water medium portion 110B is used.
- the fresh water cultivation period until the salt-tolerant seedling 102 germinates and roots is germinated and rooted by adding fresh water W2 to the sponge material 112 of the holder 115 in the fresh water medium region P1.
- the semipermeable membrane 105 is disposed between the fresh water medium part 110B and the sea water part 120B, that is, at the boundary part between the holder 115 and the sea water W1, both are isolated.
- the seawater W1 can be prevented from diffusing and adhering to 110B and the seed 102c of the salt-tolerant seedling 102 before germination and rooting, and germination and rooting can be performed without being affected by salt.
- the semipermeable membrane 105 is removed from the position of the lower surface 115b of the holder 115.
- the holder 115 and the seawater W1 are in contact with each other, and the tip of the root 102a is immersed in the seawater W1 in the seawater medium region P2.
- the salt-tolerant seedling 102 can be grown in the freshwater cultivation period and the seawater cultivation period by adding the microorganism 104 to the sponge material 112 and the seawater W1. Also, by changing the material, thickness, etc. of the semipermeable membrane 105, the timing at which the root 102a of the salt-tolerant seedling 102 adheres to the seawater W1 or the microorganism 104 can be shifted, so the speed of growing the salt-tolerant seedling 102 is adjusted. be able to.
- the cultivation system 101C according to the fifth embodiment shown in FIGS. 8A to 8C uses the holder 115 of the second embodiment described above, and is for fresh water shown in FIGS. 6A to 6C.
- the water tank 116 is omitted, and a freshwater / seawater water tank 124 is adopted.
- the freshwater / seawater tank 124 is provided with a holding portion 123 at a substantially intermediate portion in the vertical direction, and freshwater W2 or seawater W1 is stored so that the holder 115 held by the holding portion 123 has a depth to be submerged. Yes. That is, the freshwater / seawater tank 124 stores freshwater W2 during the freshwater cultivation period and stores seawater W1 during the seawater cultivation period.
- the seawater W1 at this time may be obtained by adding the seawater W1 to the freshwater W2, or by replacing the freshwater W2 with the seawater W1.
- the seed material 102c of the salt-resistant seedling 102 is seeded on the sponge material 112 of the holder 115 in the fresh water medium region P1, and the fresh water W2 stores this holder 115.
- the holder 115 is immersed in the fresh water W2 by being held in the holding portion 123 of the freshwater / seawater water tank 124, and the salt-tolerant seedling 102 germinates and roots. Subsequently, as shown in FIGS.
- the seawater W1 is introduced into the freshwater / seawater aquarium 124 and the microorganism 104 is imparted. Is done.
- the freshwater / seawater tank 124 is switched from the freshwater medium region P1 to the seawater medium region P2.
- the microorganism 104 may be applied to the fresh water W2 before or after the holder 115 is placed on the holding unit 123. Thereby, the salt-tolerant seedling 102 grown to a predetermined length by the fresh water W2 is immersed in the seawater W1.
- the holder 115 and the salt-tolerant seedling 102 are not in contact with salt and are affected by salt. It can germinate and root without any problems.
- cultivation system 101D by 6th Embodiment shown to FIG. 9A and FIG. 9B is the frame-shaped holder 117 which can hold
- (Support) is provided in the sea water tank 121.
- the support cylinder 111 has a sponge material 112 fitted inward.
- the frame-shaped holder 117 has a plate shape, and an outer peripheral edge 117b is fixed or detachably attached to a frame member 122 attached to the seawater water tank 121.
- the frame-shaped holder 117 has a plurality of holding holes 117a for fitting and holding the support cylinder 111 from above.
- the attachment position of the frame-shaped holder 117 is set at an upper position where the lower surface 111a of the support cylinder 111 held by the frame-shaped holder 117 is spaced from the water surface of the seawater W1 in the seawater tank 121 by a predetermined distance. Yes. That is, the clearance 103 is provided between the lower surface 111a of the support tube 111 and the seawater W1, and the support tube 111 held by the frame-shaped holder 117 constitutes the fresh water medium part 110D.
- the support cylinder 111 can be cultivated in an environment free from salt in the freshwater medium region P1, and the support cylinder 111 can be detached from the frame-shaped holder 117.
- the support tube 111 can be exchanged as the salt-tolerant seedling 102 grows.
- each device as shown in the first embodiment are not limited, and the capacities of the water tank 30, the seawater water supply tank 22, the freshwater water supply tank 23, the drainage tank 42, etc.
- the present invention is not limited to the embodiment described above, and can be set as appropriate.
- the shape, size, material, and the like of the semi-solid medium 31 that holds the salt-tolerant plant P are not limited to the first embodiment, and depending on the type and quantity of the salt-tolerant plant P. It can be changed as appropriate.
- microorganisms are employed in this embodiment, the present invention is not limited to microorganisms, and for example, hormone agents can be used.
- hormone agents can be used as such a hormonal agent, pyrroloquinoline quinone (for example, Patent No. 5013326) or plant hormone strigolactone (Proceedings of the National Academy of Science of USA, 111, 851-856, 2014) can be used. it can.
- the input location of microorganisms and fertilizers is not limited to the position of the water supply pipe 25 of the water supply system 20 as in the first embodiment. It doesn't matter.
- the salt tolerance-imparting agent is not imparted to the growth of the salt-tolerant seedling 102 in both the freshwater cultivation period and the seawater cultivation period, and may be imparted only in any one period.
- the sponge material 112 is used as the semi-solid medium, but the present invention is not limited to this. In short, any member can be used as long as it can support and grow the seed 102c of the salt-tolerant seedling 102 by including fresh water W2 in the support (support cylinder 111, holder 115).
- a gel-like substance or a reverse osmosis membrane may be provided.
- a bottom plate having a hole in the through hole 115a of the support cylinder 111 or the holder 115 may be provided. That is, by providing a bottom plate in which a hole having a diameter smaller than the inner diameter of the through hole 115 a of the support cylinder 111 or the holder 115 is provided, the sponge material 112 fitted in the through hole 115 a falls off from the support cylinder 111 or the holder 115. Can be prevented.
- a cultivation system 130 shown in FIGS. 11 and 12 stores a pair of water supply pumps 131 and 132 that pump seawater W1 from the sea 138, and stores seawater W1 that is pumped by the water supply pumps 131 and 132, and a salt-tolerant seedling 102 that is cultivated is disposed.
- Seawater tank 121 having freshwater medium section 110A and seawater section 120A, seawater tank 133 for temporarily storing seawater W1 pumped from sea 138 by water supply pumps 131 and 132, and freshwater tank in which freshwater W2 is stored 136, a seawater water pump 135 provided in a water supply pipe connecting the seawater tank 133 and the seawater tank 121, and a freshwater water pump 137 provided in a water supply pipe connecting the freshwater tank 136 and the seawater tank 121. It is equipped with. Seawater W1 supplied by the pair of water supply pumps 131 and 132 passes through the filter 134 and is sent to the seawater tank 133. In this cultivation system 130, the whole outline in the case of replacing the freshwater W2 in the seawater tank 121 with the seawater W1 or mixing the seawater W1 with the freshwater W2 is shown.
- FIG. 11 shows a system for supplying water to the seawater tank 121 by switching between seawater W1 from the seawater tank 133 and freshwater W2 from the freshwater tank 136.
- FIG. 11 shows a state where the fresh water W2 is stored in the seawater tank 121 from the fresh water tank 136.
- FIG. 12 shows a system for feeding seawater W1 from the seawater tank 133 and freshwater W2 from the freshwater tank 136 into the seawater tank 121 by different systems.
- FIG. 12 shows a state in which the clearance 103 is formed between the freshwater medium part 110A and the seawater W1 of the seawater part 120A in a state where the seawater W1 is stored in the seawater tank 121 from the seawater tank 133.
- seawater is applied as the salt water in the seawater medium region P2, but it is not necessarily limited to seawater, and salt water in which sodium chloride is added to water may be used. .
- the configuration such as the shape, size and quantity of the support (support cylinder 111, holder 115, frame-shaped holder 117) in the fresh water medium region P1, the position and shape of the semi-solid medium (sponge material 112, etc.) It is not limited to embodiment mentioned above, For example, it can set suitably according to conditions, such as a kind, quantity, installation space, etc. of the salt tolerance seedling 2 to grow. Further, the configuration of the seawater medium region P2 (saline medium region) can be appropriately set according to the configuration of the fresh water medium region P1, for example.
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Abstract
Description
本願は、2016年3月31日に日本に出願された特願2016-073439号、及び2016年3月31日に日本に出願された特願2016-073438号に基づき優先権を主張し、その内容をここに援用する。
また、海水を用いて栽培する場合には、バクテリアの量や不要なゴミ、更には重金属など植物の生長や人に危害を与えるものを除去する必要があり、その点で改善の余地があった。
また、塩水を用いて栽培する場合では、海水程度の濃度の培地において発根が困難であることが知られている。つまり、発芽・発根させる工程は、非常に塩濃度に敏感であることから、海水レベルでの耐塩性を植物に付与する海水育苗用の苗床の具体的な構造は実現されていない。そのため、低コストで複雑な構造にならずに、植物を塩水を用いて効果的に栽培できる構造が求められていた。
(1)本発明の一態様に係る海水を用いた水耕栽培システムは、海水を用いて耐塩植物を水耕栽培するための海水を用いた水耕栽培システムであって、塩濃度、バクテリア量、及び不要物が一定基準以下の海水を海から汲み上げる給水ポンプと、該給水ポンプで汲み上げた海水を貯水するとともに、栽培する耐塩植物が配置される水槽と、海から取水した海水中のバクテリア及び不要物を除去する除去部と、を備え、前記除去部で前記バクテリア及び前記不要物が除去された海水が前記水槽に送られることを特徴としている。
また、水槽内の海水を海に排水する流路を構成することで水槽内の海水の一部又は全ての入れ替えを簡単な構造により行うことができる。
(7)本発明の他の態様に係る播種育苗用の栽培システムは、耐塩苗を耐塩付与剤を用いて育成するための播種育苗用の栽培システムであって、前記耐塩苗を淡水によって発芽・発根させるための淡水培地領域に設けられる淡水培地部と、発根した前記耐塩苗の根を塩水に浸けて育成させるための塩水培地領域に設けられる塩水部と、を備え、少なくとも前記淡水培地部で発芽・発根させる淡水育成期間において、前記淡水培地部と前記塩水部との間に塩拡散阻害部を有することを特徴としている。
また、本発明では、淡水培地部と塩水部との間に、例えば隙間部を設けるといった簡単な構成からなる塩拡散阻害部とすることが可能となるため、設備にかかるコストを抑えることができる。
(12)上記(11)に記載の、播種育苗用の栽培システムにおいて、前記クリアランスは、1mm以上、又は10cm以上30cm以下であってもよい。
また、クリアランスの大きさを変えることで、耐塩苗の根が塩水や耐塩付与剤に付着するタイミングをずらすことができるので、耐塩苗の育成のスピードを調整することができる。
また、半透膜の材質や厚さ等を変えることで、耐塩苗の根が塩水や耐塩付与剤に付着するタイミングをずらすことができるので、耐塩苗の育成のスピードを調整することができる。
図1に示すように、本実施の形態による水耕栽培システム1は、海Sから取水した海水W1を用いて耐塩植物Pを水耕栽培するためのものである。
水耕栽培システム1は、海水W1を海Sから汲み上げる給水ポンプ21と、給水ポンプ21で汲み上げた海水W1を貯水するとともに、栽培する耐塩植物Pが配置される水槽30と、水槽30内の海水W1を排水又は後述する循環系統60を通過させて循環させる循環ポンプ41と、を備えている。
また、本水耕栽培システム1では、複数の水槽30、30、…が設けられ、水槽30毎に栽培系統3(3A、3B、3C、…)が構成されている。なお、図1では、符号3Aの1系統のみを詳細に表示し、他の系統(符号3B、3C)は破線で示している。
ここで、給水ポンプ21A、21Bによる取水は、例えば海面から表面を除く、5cm以上の海水W1とすることが好ましい。
淡水給水タンク23に繋がる淡水配管231は、送水配管25(25a)の送水弁241と送水ポンプ24との間に接続されている。淡水配管231には、淡水供給ポンプ232が設けられている。具体的には、耐塩植物Pの栽培に害を及ぼす物質などを監視することで海水W1の水質を評価したうえで、淡水供給ポンプ232を作動させ、送水配管25内の海水W1に淡水W2を混合させることで水質を安定化させることが可能な構成となっている。
また、海水W1に投入される肥料としては、例えば、液体肥料のハイポネックス(ハイポネックスジャパン社製)、固形肥料の味菜野菜の肥料(タキイ種苗社製)、有機肥料の骨粉入り有機肥料(朝日工業社製)等が挙げられる。
半固形培地31は、例えば、プラスチック、セラミック、発泡樹脂、木材等の部材により形成される矩形筒状の支持体中に多孔質状のスポンジ材が嵌合されている。このスポンジ材としては、耐塩植物Pを種から発芽・発根するまで支持できる材料からなり、例えばポリウレタン等の合成樹脂を発泡成形させた合成スポンジや、生物の海綿を加工した天然スポンジを使用することができる。
水位検出部71は、水槽30内の海水W1の水位が測定される。水位検出部71で測定された水位から水槽30内の水量が管理され、例えば微生物の投入時において水位を下げる制御が行われる。
肥料検出部72は、水槽30内の海水W1の肥料濃度が測定され、或いは海水W1の流速が測定される。肥料検出部72によって測定された肥料濃度や流速に基づいて得られる肥料濃度から上述した肥料投入部52による肥料の投入量が制御される。
塩濃度検出部74は、水槽30内の海水W1の塩濃度が測定される。塩濃度検出部74によって測定された塩濃度が例えば所定の水準よりも高い場合には、水槽30内の海水W1の一部又は全てを入れ替える制御が行われ、或いは淡水給水タンク23より淡水W2を供給することで塩濃度を調整する制御が行われる。
なお、排水タンク42は、海Sの近傍に設けることで、タンク内の海水W1を自然流下により海Sに放水することができる。なお、図示しない排水ポンプを使用して海Sに排水するようにしてもよい。
冷却装置62は、マイクロナノバブル発生器61よりも下流寄りに設けられ、溶存酸素が確保された海水W1を海水温まで冷却する機能を有している。
このように、本水耕栽培システム1では、循環系統60にマイクロナノバブル発生器61及び冷却装置62を設けることで、水槽30内の海水温度と溶存酸素濃度を一定に保つことが可能となる。
先ず、給水ポンプ21A,21Bにより海Sから海水W1を汲み上げ、フィルタ27を通過させて海水給水タンク22に貯水される。このとき、海水W1のバクテリア、及び不要物がフィルタ27によって除去される。また、淡水給水タンク23には、図示しない淡水源(川や水道)から淡水W2が貯水される。
その後、送水ポンプ24による送水流路を淡水給水タンク23から海水W1が貯水されている海水給水タンク22に切り替え、その海水W1を水槽30に供給して貯水する。このとき、最初の段階では、微生物との接触機会を増やすために海水W1の水位を定常時よりも低くなるように設定する。なお、水槽30内の海水W1の水位を低く保つことで、微生物の投入量を低減できる利点もある。
図1に示すように、本実施の形態では、海Sから塩濃度、バクテリア量、及び不要物が一定基準以下の海水W1を給水ポンプ21で汲み上げ、この海水W1のバクテリア、及び不要物をフィルタ27で除去した後に水槽30に供給して貯水することができ、これにより水槽30内で耐塩植物Pを水耕栽培することができる。
このように海Sから取水した海水W1を利用した水耕栽培システム1となるので、大規模で生産性の高い海水水耕栽培の場を実現することができる。
さらにまた、水槽30内の海水W1を海Sに排水する排水系統40を構成することで、水槽30内の海水W1の一部又は全ての入れ替えを簡単な構造により行うことができる。
図2及び図3A~図3Cに示すように、本実施の形態による播種育苗用の栽培システム101は、耐塩苗102を耐塩付与剤を用いて育成するものであって、淡水W2とともに海水W1(塩水)を用いて耐塩苗102の栽培を行うものである。
栽培システム101は、耐塩苗102を淡水W2によって発芽・発根させるための淡水培地領域P1に設けられる淡水培地部110と、発根した耐塩苗102の根102aを海水W1に浸けて育成させるための海水培地領域P2に設けられる海水部120(塩水部)と、を備えている。
そして、淡水栽培期間における淡水培地部110及び海水部120の間には、クリアランス103(塩拡散阻害部)が形成されている。
スポンジ材112は、支持筒111内において淡水W2を含んで耐塩苗102を種102cから発芽・発根するまで支持できる材料からなり、例えばポリウレタン等の合成樹脂を発泡成形させた合成スポンジや、生物の海綿を加工した天然スポンジを使用することができる。
ここで、微生物104としては、例えば、Journal of Plant Interactions, Volume 9, Issue 1, 2014に開示される微生物等を適用することができる。
図2に示すように、本実施の形態では、図3Aに示すように、淡水培地部110のスポンジ材112に含ませた淡水W2に耐塩苗102の種102cを播種する。このときの種102cは、スポンジ材112の上面に載置するだけでも良いし、スポンジ材112の表層部分に埋め込むように配置しても良い。これにより、種102cは、図3Bに示すように、スポンジ材112に含まれる淡水W2に接して発芽・発根する。さらに、スポンジ材112に対して適宜なタイミングで微生物104を付与する。これにより、スポンジ材112内で伸びている根102aに微生物104が付着することで、芽102b及び根102aを育成させることが可能となる。
このように、塩の付着により悪影響を及ぼす発芽・発根前の播種の段階では、海水W1から隔離された淡水W2のみで耐塩苗102を育成することができ、ある程度根が伸びて塩が育成を促進させる段階で、海水部120における海水W1により育成することが可能となる。そのため、耐塩苗102を枯死させることなく生産性を向上させることができる。
また、本実施の形態では、淡水培地部110と海水部120との間に、クリアランス103を設けるといった簡単な構成となるため、設備にかかるコストを抑えることができる。
また、この場合には、耐塩苗102の育成中に微生物104が付着されるため、耐塩苗102を育成させることができる。
また、クリアランス103の大きさ(高さ)を変えることで、耐塩苗102の根102aが海水W1や微生物104に付着するタイミングをずらすことができるので、耐塩苗102の育成のスピードを調整することができる。
しかも、本実施の形態では、クリアランス103を1mm以上、又は10cm以上で30cm以下の範囲に設定することで、淡水培地部110や種102cに塩水が拡散することをより確実に抑えることができる。
図4に示す第3の実施の形態による栽培システム101Aは、複数のスポンジ材112を配設させたホルダー115(支持体)を有する淡水培地部110Aが設けられている。
ホルダー115は、図5に示すように、例えば、発泡スチロール、プラスチック、木材、石膏ボード等の軽量で水に浮く素材からなる板状部材をなし、面方向に沿って所定の間隔をあけて厚さ方向に貫通する複数の貫通孔115aが形成されている。複数のスポンジ材112には、複数の貫通孔115aのそれぞれに嵌入されている。なお、貫通孔115aは、図4に示すように縦横に一定の間隔をあけて配列されることに制限されず、栽培する耐塩苗102の種類等に合わせて適宜に配置することができる。
また、図4に示すように、海水部120Aには、上記の淡水用水槽116とは別体で設けられ、海水W1が貯留される海水用水槽121が設けられている。海水用水槽121には、図6Dに示すように、枠材122が連設されており、この枠材122にホルダー115を着脱可能に保持する保持部123が設けられている。保持部123は、L字状に形成され、海水用水槽121の周方向に沿って全周又は部分的に配置され、ホルダー115を下方から支持する構成となっている。なお、保持部123の取り付け位置は、海水用水槽121内の海水W1の水面から所定の間隔をあけた上方の位置に設定されている。つまり、保持部123に保持されるホルダー115の下面115bと海水W1との間にはクリアランス103が設けられた状態となる。
先ず、図6Aに示すように、淡水培地領域P1においてホルダー115の複数のスポンジ材112のそれぞれに耐塩苗102の種102cを播種した後、ホルダー115を淡水用水槽116に貯留された淡水W2内に浸水させる。その後、図6B、図6Cに示すように、耐塩苗102が発芽・発根した適宜なタイミングで、スポンジ材112に微生物104を付与する。続いて、図6Dに示すように、耐塩苗102の根102aがホルダー115の下方に伸び出した状態で、ホルダー115を淡水用水槽116から取り出して海水用水槽121の保持部123に保持させる。これにより、ホルダー115はクリアランス103をもって海水W1の上方に配置される。
そして、海水W1には、適宜なタイミングで微生物104が付与されている。この微生物104の付与するタイミングは、ホルダー115を保持部123に配置する前、あるいは配置した後のいずれでもかまわない。これにより、海水培地領域P2において淡水W2によって所定の長さに育成した耐塩苗102の根102aの先端が海水W1に浸かることになる。
さらに、この場合には、淡水用水槽116が、海水用水槽121とは別体で離れた位置に設けられるので、淡水用水槽116内の淡水W2で発芽・発根の際の耐塩苗2が塩に接することを防ぐことができる。
また、本実施の形態のように複数のスポンジ材112(耐塩苗102)に対してホルダー115が設けられる場合には、1つのホルダー115のみを海水部120に対して交換することで複数の耐塩苗2を同時に交換することができ、作業の効率化を図ることができる。
次に、図7に示す第4の実施の形態による栽培システム101Bは、上述した第2の実施の形態と同様のホルダー115と海水W1との間の境界部分にフィルム状の半透膜105(塩拡散阻害部)を着脱可能に配置した構成となっている。
半透膜105は、ホルダー115の下面115bを覆った状態で配設されている。半透膜105として、海水W1の塩が淡水培地部110B寄りのホルダー115に向けて透過しない材料のものが用いられる。
また、半透膜105の材質や厚さ等を変えることで、耐塩苗102の根102aが海水W1や微生物104に付着するタイミングをずらすことができるので、耐塩苗102の育成のスピードを調整することができる。
次に、図8A~図8Cに示す第5の実施の形態による栽培システム101Cは、上述した第2の実施の形態のホルダー115を用いたものであって、図6A~図6Cに示す淡水用水槽116が省略され、淡水・海水用水槽124を採用したものである。淡水・海水用水槽124は、上下方向の略中間部分に保持部123が設けられ、この保持部123に保持されるホルダー115が浸水される深さとなるように淡水W2又は海水W1が貯留されている。つまり、淡水・海水用水槽124には、淡水栽培期間において淡水W2が貯留され、海水栽培期間において海水W1が貯留される。このときの海水W1は、淡水W2に海水W1を追加したものでも良いし、淡水W2を海水W1に入れ替えることによるものでも良い。
第5の実施の形態では、淡水栽培期間において淡水・海水用水槽124には淡水W2のみが貯留されているので、ホルダー115及び耐塩苗102が塩に接することはなく、塩の影響を受けることなく発芽・発根することができる。
次に、図9A、図9Bに示す第6の実施の形態による栽培システム101Dは、上述した第1の実施の形態の支持筒111(支持体)を複数保持することが可能な枠状ホルダー117(支持体)が海水用水槽121内に設けられている。支持筒111は、第1の実施の形態と同様に内寄りにスポンジ材112が嵌入されている。
枠状ホルダー117は、板状をなし、外周縁117bが海水用水槽121に取り付けられた枠材122に固定、又は着脱自在に取り付けられている。枠状ホルダー117には、支持筒111を上側より嵌合させて保持する保持穴117aが複数形成されている。そして、枠状ホルダー117の取り付け位置は、枠状ホルダー117に保持された支持筒111の下面111aが海水用水槽121内の海水W1の水面から所定の間隔をあけた上方の位置に設定されている。つまり、支持筒111の下面111aと海水W1との間にはクリアランス103が設けられた状態となり、枠状ホルダー117に保持された支持筒111は淡水培地部110Dを構成している。
なお、海水W1には、予め微生物104を付与しておくことで、海水W1に浸かった根102aに微生物104を付着させることができる。
図12は、海水タンク133からの海水W1と淡水タンク136からの淡水W2とをそれぞれ別系統で海水用水槽121内に送水するシステムを示している。図12では、海水タンク133から海水用水槽121内に海水W1を貯水した状態で、淡水培地部110Aと海水部120Aの海水W1との間にクリアランス103が形成された状態を示している。
また、海水培地領域P2(塩水培地領域)の構成に関しても、例えば淡水培地領域P1の構成に合わせて適宜設定することができる。
3、3A、3B、3C 栽培系統
20 送水系統
21、21A、21B 給水ポンプ
22 給水タンク
23 淡水給水タンク
24 送水ポンプ
25 送水配管
27 フィルタ(除去部)
30 水槽
31 半固形培地
40 排水系統
41 循環ポンプ
42 排水タンク
43 排水処理部
50 育成促進材供給系統
51 微生物投入部
52 肥料投入部
60 循環系統
61 マイクロナノバブル発生器(溶存酸素供給部)
62 冷却装置(海水温度調節部)
70 水槽監視部(監視部)
71 水位検出部
72 肥料検出部
73 微生物検出部
74 塩濃度検出部
101、101A~101E 栽培システム
102 耐塩苗
102a 根
103 クリアランス(塩拡散阻害部)
104 微生物(耐塩付与剤)
105 半透膜(塩拡散阻害部)
110、110A、110B、110D 淡水培地部
111 支持筒(支持体)
112 スポンジ材(半固形培地)
115 ホルダー(支持体)
115a 貫通孔
116 淡水用水槽
117 枠状ホルダー(支持体)
120、120A、120B、120D 海水部(塩水部)
121 海水用水槽
123 保持部
P 耐塩植物
S 海
W1 海水(塩水)
W2 淡水
Claims (15)
- 海水を用いて耐塩植物を水耕栽培するための海水を用いた水耕栽培システムであって、
塩濃度、バクテリア量、及び不要物が一定基準以下の海水を海から汲み上げる給水ポンプと、
該給水ポンプで汲み上げた海水を貯水するとともに、栽培する耐塩植物が配置される水槽と、
海から取水した海水中のバクテリア及び不要物を除去する除去部と、
を備え、
前記除去部で前記バクテリア及び前記不要物が除去された海水が前記水槽に送られることを特徴とする、海水を用いた水耕栽培システム。 - 前記除去部では、溶存酸素や重金属による前記耐塩植物の生長を阻害する物質、及び人に危害を及ぼす物質を除去する機能を有することを特徴とする、請求項1に記載の海水を用いた水耕栽培システム。
- 前記水槽に供給される前の海水と、前記水槽に供給された後の海水の性状を検出する監視部が設けられていることを特徴とする、請求項1又は2に記載の海水を用いた水耕栽培システム。
- 前記海水の一部又は全てが交換可能に設けられていることを特徴とする、請求項1乃至3のいずれか1項に記載の海水を用いた水耕栽培システム。
- 前記水槽に供給される前記海水の温度を調整する海水温度調節部が設けられていることを特徴とする、請求項1乃至4のいずれか1項に記載の海水を用いた水耕栽培システム。
- 前記水槽に供給される前記海水に溶存酸素を供給する溶存酸素供給部が設けられていることを特徴とする、請求項1乃至5のいずれか1項に記載の海水を用いた水耕栽培システム。
- 耐塩苗を耐塩付与剤を用いて育成するための播種育苗用の栽培システムであって、
前記耐塩苗を淡水によって発芽・発根させるための淡水培地領域に設けられる淡水培地部と、
発根した前記耐塩苗の根を塩水に浸けて育成させるための塩水培地領域に設けられる塩水部と、
を備え、
少なくとも前記淡水培地部で発芽・発根させる淡水育成期間において、前記淡水培地部と前記塩水部との間に塩拡散阻害部を有することを特徴とする、播種育苗用の栽培システム。 - 前記淡水培地部は、前記塩水部に対して着脱可能な支持体を備え、
前記支持体は、前記塩水部の塩水よりも上方に位置していることを特徴とする、請求項7に記載の播種育苗用の栽培システム。 - 前記耐塩付与剤は、前記淡水培地部の淡水及び前記塩水部の塩水の少なくとも一方に付与されていることを特徴とする、請求項7又は8に記載の播種育苗用の栽培システム。
- 前記耐塩付与剤は、微生物であることを特徴とする、請求項7乃至9のいずれか1項に記載の播種育苗用の栽培システム。
- 前記塩拡散阻害部は、前記淡水培地部と前記塩水部の塩水との間に形成されるクリアランスであることを特徴とする、請求項7乃至10のいずれか1項に記載の播種育苗用の栽培システム。
- 前記クリアランスは、1mm以上、又は10cm以上30cm以下であることを特徴とする、請求項11に記載の播種育苗用の栽培システム。
- 前記塩拡散阻害部は、前記淡水培地部と前記塩水部の塩水との間に設けられるフィルム状の半透膜であることを特徴とする、請求項7乃至10のいずれか1項に記載の播種育苗用の栽培システム。
- 前記淡水培地部は、塩の浸入を阻害する半固形培地を有していることを特徴とする、請求項7乃至13のいずれか1項に記載の播種育苗用の栽培システム。
- 前記塩水部は、塩拡散を阻害する半固形培地を有していることを特徴とする、請求項7乃至14のいずれか1項に記載の播種育苗用の栽培システム。
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- 2017-02-27 AU AU2017242044A patent/AU2017242044A1/en not_active Abandoned
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- 2017-02-27 SG SG11201806554UA patent/SG11201806554UA/en unknown
- 2017-02-27 CN CN201780009531.9A patent/CN108601328A/zh active Pending
- 2017-02-27 EP EP17773971.1A patent/EP3437463A4/en not_active Withdrawn
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US20190037788A1 (en) | 2019-02-07 |
SG11201806554UA (en) | 2018-10-30 |
JPWO2017169426A1 (ja) | 2018-04-05 |
JP2018086024A (ja) | 2018-06-07 |
CN108601328A (zh) | 2018-09-28 |
EP3437463A4 (en) | 2020-01-15 |
JP6304732B2 (ja) | 2018-04-04 |
EP3437463A1 (en) | 2019-02-06 |
US11343984B2 (en) | 2022-05-31 |
AU2017242044A1 (en) | 2018-08-16 |
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