JP2014212723A - Apparatus and method for aquaculture of aquatic organism, and apparatus and method for hydroponic culture of plant - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus and method for aquaculture of aquatic organisms, and an apparatus and method for hydroponic culture of plants, which can also be utilized by facilities and industry of breeding aquatic organisms in addition to the facilities of marine products using hydrogen gas, and further, can also be utilized on the surface of sea in addition to indoor and outdoor facilities on land, and furthermore, can be applied to the hydroponic culture of plants.SOLUTION: An apparatus for aquaculture of aquatic organisms includes at least a device for storing aquaculture water to culture the aquatic organisms, a hydrogen gas feeding device for supplying hydrogen gas in the aquaculture water, and a blowing device to blow the hydrogen gas into the aquaculture water. Also, a method for aquaculture of the aquatic organisms using the apparatus is provided. An apparatus for hydroponic culture of plants includes at least a device for storing a culture solution for hydroponic culture of the plants, a hydrogen gas feeding device for supplying the hydrogen gas in the culture solution, and a blowing device to blow the hydrogen gas into the culture solution. Also, a method for hydroponic culture of the plants using the apparatus is provided.

Description

  The present invention provides a device for cultivating aquatic organisms, a method for cultivating aquatic organisms using the same, and a device for hydroponically cultivating a plant using a hydrogen gas that is widely used in a simple manner. The present invention relates to a hydroponics method for plants.

  In recent years, for example, at aquaculture sites, the target fish and shellfish and the aquatic organisms that serve as their feed have been cultured and bred. In such cases, animal drugs, etc. are often used to combat fish diseases and improve yields. May be used. However, this is a problem in terms of food safety due to an increase in breeding costs and chemical damage.

On the other hand, in the health industry field, the market for products using hydrogen is booming, with hydrogen water and hydrogen supplements at the center.
According to a study by Ota et al. (Non-patent Document 1), it has been found that hydrogen reduces oxygen radicals in rats and exhibits a therapeutic antioxidant effect. At present, antioxidative stress effect, anti-inflammatory effect, anti-allergic effect, energy metabolism enhancing effect and the like via cells and tissues have been confirmed.

Although the effect of hydrogen on humans has been clarified, there is an example in which animals and plants other than the human health field are applied to aquatic organisms and plants such as fish (Patent Document 1). According to Patent Document 1, the effect of hydrogen is considered to be suppression of bacterial growth and prevention of root rot of circulating nutrient solution for plants, and suppression of deterioration of breeding water environment and prevention of fish diseases for fisheries. Both are expecting improved productivity.
However, Patent Document 1 uses a hydrogen-oxygen mixed gas in which hydrogen and oxygen are mixed, not a technique using the hydrogen gas itself, and an apparatus for producing the mixed gas is complicated and costly. There is also a problem that it takes.

JP 2009-22211 A

Ohta et al. (2007): Hydrogen acts as atherapeutic antioxidant by selectively reducing cytotoxic oxygen radicals. Naturemedicine 13,688-694 (1 June 2007) (URL: http://www.nature.com/nm/journal/vaop/ncurrent/ abs / nm1577.html)

  The present invention uses hydrogen gas itself, can be used for fisheries facilities, equipment for breeding aquatic organisms and industry, and can also be used on land, indoor and outdoor facilities, and also on the sea surface. Another object of the present invention is to provide a water tank bioculture device and a water tank bioculture method, a plant hydroponic culture apparatus and a plant hydroponic method that can be applied to hydroponics of plants.

The present invention includes at least an apparatus for storing aquaculture water for aquaculture of aquatic organisms, a hydrogen gas supply apparatus for supplying hydrogen gas to the aquaculture water, and a blowing apparatus for blowing the hydrogen gas into the aquaculture water. The present invention relates to aquatic aquaculture equipment.
The present invention also relates to a method for culturing aquatic organisms, wherein the aquatic organism culturing apparatus is used to cultivate aquatic organisms in an apparatus for storing aquaculture water.
Next, the present invention provides at least a device for storing a culture solution for hydroponically cultivating a plant, a hydrogen gas supply device for supplying hydrogen gas to the culture solution, and a blow for blowing the hydrogen gas into the culture solution. The present invention relates to a plant hydroponic cultivation apparatus.
Moreover, this invention relates to the plant hydroponics method of using the said plant hydroponics apparatus and hydroponically cultivating a plant in the apparatus which stores a culture solution.

  According to the present invention, hydrogen gas itself has the effect of alleviating the effects of starvation on aquatic organisms such as plankton or delaying the time of starvation (life extension). Further, according to the present invention, it can be used not only for fisheries facilities but also for equipment and industry for breeding aquatic organisms, and also for indoor and outdoor facilities on land, and also at sea level. It is possible to provide an aquatic organism culture device and an aquatic organism cultivation method, a plant hydroponics device, and a plant hydroponics method that can be applied to hydroponics of the plant.

In one Embodiment of this invention, it is the schematic of the aquatic aquaculture apparatus using the hydrogen gas used for a present Example. Batch No. in this example. In the graph showing the results of 1, the horizontal axis is the number of days of hatching of Artemia larvae Nauplii and the vertical axis is the number of surviving individuals.

<Aquatic aquaculture equipment>
The aquatic aquaculture apparatus according to the present invention includes at least an apparatus for storing aquaculture water for aquaculture of aquatic organisms, a hydrogen gas supply apparatus for supplying hydrogen gas to the aquaculture water, and for blowing this hydrogen gas into the aquaculture water. A blowing device is provided.

Equipment for storing aquaculture water:
As an apparatus for storing the aquaculture water in the present invention, a water tank for aquatic aquaculture is first mentioned. An aquatic aquaculture tank is a tank for raising seafood and the like. The structure of the aquarium is not particularly limited, but it is preferable to have a function of collecting and discharging sedimentary suspended solids such as residual food and fish and shellfish in one place. For example, the planar shape is circular or polygonal, it has a cylindrical drainage part in the center, and the sedimentary suspended solids at the bottom are collected in the central part using the negative pressure of the water flowing out downward, and the sedimentary suspension is collected. As the turbid substance concentrated water, a water tank that flows out separately from the water stream of the supernatant is particularly preferably used. With such a water tank, the outflow water from the water tank containing suspended solids can be efficiently discharged.

There are no particular restrictions on the components of the aquarium, but the foundation and struts are made of concrete, steel, etc., a reinforced plastic wall frame is installed on the foundation and in the strut, and a waterproof sheet is stretched on the inner surface of the wall frame. A water tank is preferable, which is a water tank in which a heat insulating material made of foam plastic is incorporated between the bottom of the sheet and the foundation. Of course, a water tank made of reinforced concrete manufactured integrally or a water tank made of reinforced plastic or reinforced concrete divided by a plane passing through the central axis and waterproofed with an adhesive or a sealing agent may be used.
As an apparatus for storing the aquaculture water in the present invention, in addition to the aquaculture tank described above, a ready-made resin or glass aquarium, or a living aquarium may be used.

Hydrogen gas supply device:
There are several methods for producing hydrogen gas, but the most known method is electrolysis of water. This method has also been used as a method for industrial production since ancient times. That is, when ordinary water is electrolyzed, oxygen gas is generated from the anode side (+: positive electrode), and hydrogen gas is generated from the cathode side (−: negative electrode). Decomposing salt solution instead of water produces hydrogen, chlorine, and caustic soda (sodium hydroxide: NaOH). However, water electrolysis requires a large amount of electric power, and since it is high in purity, it is industrially used, such as a steam reforming method.
For example, when hydrogen gas is blown into heavy oil, the heavy oil decomposes and changes to light oil. Similarly, when water vapor is blown into light oil, the oil decomposes and hydrogen gas is generated. Even when water vapor is blown into a hydrocarbon gas such as methane gas, hydrogen gas can be obtained in the same manner. In the case of methane gas, it decomposes into hydrogen and carbon monoxide and hydrogen and carbon dioxide.
CH ₄ + H ₂ O → CO + 3H ₂
CH ₄ + 2H ₂ O → CO ₂ + 4H ₂
From the viewpoint of cost, the hydrogen gas used in the present invention is preferably obtained by steam reforming of such hydrocarbons depending on the scale of the aquatic aquaculture apparatus.
Examples of the hydrogen gas supply device include a hydrogen cylinder and a hydrogen gas production device.
This hydrogen gas supply device is connected to a hydrogen gas blowing device (aeration pipe) installed in an aquatic aquaculture tank, for example, by a pipe (not shown).

Hydrogen gas blowing device:
The hydrogen gas blowing device is not particularly limited. For example, an air diffuser (diffuser) with a large number of fine vent holes is placed in an aquaculture area such as in an aquarium or in a living area, or in a stock tank for replacement aquaculture water. Examples include a method of supplying gas and diffusing into the aquaculture water as fine bubbles from a vent, and a method of entraining hydrogen gas using a pump for circulating the aquaculture water. The air diffuser tube is not particularly limited as long as the air hole is perforated, but from the viewpoint that fine bubbles can be diffused, the cylindrical air tube formed with the air hole and the outer peripheral surface of the air vent tube And a porous body in which particles of sintered metal, alumina, ceramics, and the like are integrated and formed are preferable.

<Aquaculture method>
In the aquatic aquaculture method of the present invention, hydrogen gas is blown into aquatic aquaculture water. Aquaculture water can be appropriately selected according to the type of aquatic organisms, and examples include seawater, brackish water, and fresh water. The aquaculture water may or may not contain minerals.

Hydrogen gas supply volume (VVH: gas supply volume per hour (m ³ / m ³ / H)) can be appropriately selected depending on the type of aquatic organisms, the shape of the aquarium for inhabiting aquatic organisms, etc. Although not particularly limited, it is usually 0.005 to 0.5 / H, preferably 0.02 to 0.1 / H. If it is less than 0.005 / H, the effect of hydrogen may be difficult to obtain. On the other hand, if it exceeds 0.5 / H, the degree of effect remains unchanged and hydrogen gas may be wasted. The supply of hydrogen gas may be performed continuously or intermittently. The supply amount of hydrogen gas can be easily controlled by, for example, a flow rate adjusting valve.
In the present invention, the means for supplying hydrogen gas is not particularly limited. The shortest example is a hydrogen gas cylinder, and in addition, means for supplying from a hydrogen gas production apparatus may be used.

  In addition, the aquatic aquaculture apparatus used in the present invention includes instruments conventionally used for breeding aquatic organisms such as filtration devices, water thermometers and water temperature controllers, pH measuring devices, lighting devices, pumps, and piping. And a device may further be included.

  The aquatic organisms to which the aquatic organism aquaculture apparatus and the cultivation method of the present invention can be applied are not particularly limited. For example, planktons such as artemia, hornworm, chlorella, shellfish such as lobster, tiger prawn, king crab, king crab, snow crab; squid, octopus; tuna, salmon, cod, flounder, flounder, Thailand, skipjack, eel, Food fish such as pufferfish, trout; shellfish such as abalone, turban shell, clam, clam, clam; ornamental fish such as angelfish, neon tetra, coral, goldfish; tropical fish such as discus, arowana, corydoras; dolphin, orca, todo, Aquatic mammals such as sea lions and sea otters; aquatic plants such as matsumo, pearl grass, chrysanthemum, seri, chromo, and star range; seaweeds such as seaweed, kombu, asao, hijiki, cedar, and mozuku; .

<Plant hydroponics device and plant hydroponics method>
In the present invention, hydrogen gas can be applied to a plant hydroponic cultivation apparatus (method) in the same manner as the above-described aquatic organism cultivation apparatus (method).
That is, the plant hydroponic cultivation apparatus of the present invention comprises at least a device for storing a culture solution for hydroponically cultivating a plant, a hydrogen gas supply device for supplying hydrogen gas to the culture solution, and the hydrogen gas as a culture solution. The plant hydroponic cultivation method of the present invention uses this plant hydroponic cultivation apparatus and hydroponically cultivates the plant in the apparatus for storing the culture solution.

  What is necessary is just to select the culture solution used for this invention suitably from the culture solutions used for the conventional hydroponics according to the plant cultivated. The culture solution contains raw water and, if necessary, organic fertilizers and inorganic fertilizers that become plant nutrients. Furthermore, a bactericide, an insecticide, a rooting agent, etc. may be contained in the culture solution as needed. The raw material water used for the culture solution is not particularly limited as long as it does not impair plant growth. In the present invention, components other than the raw material water in the culture solution may be added after blowing hydrogen gas.

  In addition, you may select suitably the apparatus which stores the culture solution used for this invention according to the form of hydroponics. For example, in submerged hydroponics, the cultivation bed itself is used as a means for storing the culture solution. In thin film hydroponics, a tank or the like storing a culture solution to be supplied to the inclined surface can be used.

  The hydrogen gas supply device and the hydrogen gas blowing device are the same as those described in the aquatic organism aquaculture device. The supply amount of hydrogen gas (VVH) can be appropriately selected depending on the type of plant, the shape of a water tank for storing a culture solution, and the like, and is not particularly limited.

  In the hydroponic cultivation apparatus of the present invention, a solid medium other than soil may be provided depending on the type of plant. Examples of solid media include rock wool, gravel such as vermiculite, and sand. Furthermore, the hydroponic cultivation apparatus of the present invention is conventionally used for hydroponic cultivation such as lighting devices, water thermometers and water temperature controllers, pH measuring devices, thermometers, hygrometers, pumps, piping, anti-frost fans, greenhouses, and filtration devices. An instrument or device used from

  The plant applicable to the hydroponic cultivation apparatus (and method) of the present invention is not particularly limited. For example, lettuce, rhubarb, mizuna, herb, radish, wasabi, bonsai, bokusai, pakchoi, cabbage, rape, spring chrysanthemum, empty core, komatsuna, Chinese cabbage, sertus, tarsai, honey, nozawana, spinach Leafy vegetables such as green onions, chili, paprika, melon, bitter gourd, watermelon, pumpkin, blueberry, strawberry, eggplant, tomato, grape and other fruit vegetables, broccoli, cauliflower, Fukinoto and other legumes, coconut, green soybeans, roses And cereals such as rice and wheat, root vegetables such as lotus root, and bulbs such as hyacinth, crocus and tulip.

  In the hydroponics method of the present invention, a plant is grown by blowing hydrogen gas into the culture solution while contacting the plant root with a solution obtained by dissolving the plant root in the culture solution. Examples of the method of bringing the liquid into contact with the root include, for example, a method in which the root is immersed in the liquid, a method in which the liquid is sprayed on the root, a method in which the root is stretched on the surface of the solid medium or the inclined surface, and the liquid is allowed to flow there. There is a method of supplying the liquid around the root using the capillary action of a solid medium such as Iwako).

Hereinafter, the present invention will be described more specifically with reference to examples.
Example 1 (Artemia larva Nauplius rearing experiment)
<Experiment details>
A breeding experiment was conducted to verify the effect of hydrogen gas supply to the breeding environment water on Artemia salina larval nauplius.
The hatched Nauplius consumes the yolk and starts predation about 3 days after the third molting, but if it continues to feed without food, it will starve and die in about a week.
In this experiment, we set up a zone where hydrogen gas was supplied to the breeding environment and a control zone where it was not supplied, and larvae hatched in both experimental zones were fed without feeding. Attention was paid to verifying whether hydrogen supply would have a life-prolonging effect. Breeding was carried out in a batch system and was performed under no-feeding conditions.

<Experiment method>
(1) Materials Artemia Endurance Egg: Tetra Japan Tetra Brine Shrimp Egg Artificial Seawater: Vertec Japan Bel Salt Premium (powder; dissolved in tap water)
(2) Equipment Breeding tank: 3 liter glass beaker Hydrogen supply: Hydrogen gas cylinder / mass flow controller / diffuser (sintered metal; made of SUS)
Hydrogen supply volume: VVH (* 1) = 0.02, 0.1, 0.3 / H
* 1) VVH: Gas supply volume per tank capacity per hour (m ³ / m ³ / H)
Aeration: Air pump / diffuser (air stone)
Temperature controller: Thermostat A schematic diagram of the experimental apparatus is shown in FIG.

(3) Experimental procedure (a) Hatching
1 g of durable eggs were inoculated into 5 L of artificial seawater at a concentration of 20 g / L, and cultured for 1 to 2 days at a water temperature of 28 ° C. while aerated, followed by breeding.
(B) Rearing
Two sections (one tank each) of a hydrogen supply section and a control section were set using a 3L beaker as a breeding tank, and water temperature control (25-28 ° C), aeration, and release were used as common breeding conditions.
After sufficiently counting hatched individuals (a) according to the counting procedure of (c), set the initial number of individuals, take the same amount in 2 tanks, and replenish artificial seawater (20 g / L concentration) as appropriate 3L.
The initial population was 40,000-60,000 individuals / tank.
Hydrogen gas was supplied to the hydrogen supply zone at a constant flow rate by adjusting the flow rate of hydrogen gas from a cylinder with a mass flow controller.
Water that evaporates during breeding was supplemented with tap water each time.
Individuals dying during breeding were not removed and breeding was continued as they were, and batch breeding was terminated when it was difficult to visually check the surviving individuals in any experimental section.
(C) Counting Take a certain amount of breeding water in which larvae are uniformly dispersed and floated by aeration, visually count the number of surviving individuals, and calculate the average value obtained by performing this multiple times. It was a number.
Judgment of life and death of larvae was mainly based on the presence or absence of swimming and antennal activity.

<Result>
The results are shown in Tables 1-2.
In the control group, the number of surviving individuals decreased to about 70% from the start of breeding to about 70% throughout the beginning of the breeding, and then showed a tendency to rapidly drop to below 30% when hunger started.
On the other hand, batch no. In the 1 hydrogen supply zone, the number of surviving individuals decreased gradually even after the hunger rush, and it remained almost linear until the 9th day, showing a clear difference from the control zone (Fig. 2).
In all batches, the number of surviving animals at the end of the breeding period was predominant in the hydrogen supply area.

<Effect>
In this example, hydrogen had a life prolonging effect on Artemia larva Nauplius, which alleviated the effect of starvation or delayed the time of starvation.
Therefore, according to the present invention, hydrogen gas itself can be used not only for fisheries facilities but also for equipment and industry for breeding aquatic organisms. Furthermore, in addition to indoor and outdoor facilities on land, also at sea level. Further, it is possible to provide an aquatic organism culture device and an aquatic organism cultivation method, a plant hydroponics device and a plant hydroponics method that can be used and can also be applied to hydroponics of plants.

  The aquatic organisms grown using the aquatic aquaculture device of the present invention are expected to have a life-prolonging effect, are less susceptible to diseases, have a strong fertility, can maintain a healthy body, and can reduce the frequency of water changes. It is useful for aquatic aquaculture. In addition, plants cultivated using the hydroponic cultivation apparatus of the present invention do not cause root rot, are excellent in the growth of flowers and fruits, and are expected to extend the life of flowers, It is also useful for hydroponics.

Claims (4)

  An aquatic organism comprising at least a device for storing aquaculture water for culturing aquatic organisms, a hydrogen gas supply device for supplying hydrogen gas to the aquaculture water, and a blowing device for blowing the hydrogen gas into the aquaculture water Aquaculture equipment.   A method for aquatic aquaculture using the aquatic aquaculture apparatus according to claim 1, wherein aquatic organisms are cultivated in an apparatus for storing aquaculture water.   A plant comprising at least an apparatus for storing a culture solution for hydroponically cultivating a plant, a hydrogen gas supply device for supplying hydrogen gas to the culture solution, and a blowing device for blowing the hydrogen gas into the culture solution Hydroponic cultivation equipment.   A plant hydroponic cultivation method, wherein the plant hydroponic cultivation apparatus according to claim 3 is used for hydroponic cultivation of a plant in an apparatus for storing a culture solution.