JP2022127526A - Spray system of microbe exterminating agent and microbe extermination method - Google Patents

Abstract

To provide a spray system of microbe exterminating agent and a microbe extermination method capable of exterminating harmful microbes continuously for long time even in a middle layer area to a deep layer area that are deeper than a front layer area in a water area as well as the front layer area in water.SOLUTION: In a spray system of microbe exterminating agent that sprays a microbe exterminating agent into water, the microbe exterminating agent is impregnated in a member having uniform openings, the microbe exterminating agent is suspended correspondingly to a depth of an inhabitation region of microbes to be exterminated, the microbes living in the water, and the microbe exterminating agent is sprayed to be diffused in the water by passing through the openings of the member.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a spraying system for diffusely spraying a microbial exterminator in water and a method for exterminating microorganisms.

Every year, red tides occur in the Yatsushiro Sea, Ariake Sea, Seto Inland Sea, and other sea areas in the Kyushu, Chugoku, and Shikoku regions. The phytoplankton that causes red tide differs from region to region. In recent years, three types of phytoplankton of the genus Chattonella, Calenia, and Cochlodinium have been regarded as major problems.

Different species of phytoplankton appear depending on the water depth from the sea surface. In addition, even for the same type of phytoplankton, the water depth that appears differs depending on the time of day. For example, Schattnera and Cochlodinium appear near the sea surface during the day for photosynthesis. Carenia appears at depths of 5 to 7 m during the day.
For example, Schattnera is a phytoplankton with a cell length of 50-130 μm. It is a species that is harmful to fish and shellfish, and there is an example of killing fish at about 40 cells/mL.

When phytoplankton appear in the surface layer (near the sea surface), the water just below the red tide caused by phytoplankton becomes hypoxic. This causes fish mortality. Therefore, effective extermination of phytoplankton, which causes red tide and the like, is desired.

Poisonous plankton is also present in red tide-causing plankton. For example, the genera Alexandrium and Dinophysis. When shellfish take in these substances along with seawater and accumulate them in their bodies, the former results in paralytic shellfish poison, while the latter results in diarrheal shellfish poison. Effective extermination is required also for these plankton.

Acid clay (Iriki Montmori (trade name)) produced in Kagoshima Prefecture is used as a red tide exterminator.
Acidic clay alone has the effect of exterminating phytoplankton, but it has to be sprayed in large quantities, which raises the problem of high running costs. In addition, by adding alum to the acid clay, aluminum ions (Al ³⁺ ) in the acid clay are facilitated to be eluted, and the extermination effect is enhanced. However, the high cost of alum and the difficulty of properly formulating it in the field are problems. Both methods are effective only in the surface layer of the ocean where they are applied.

Patent Document 1 describes that spraying magnesium oxide (MgO) is effective in exterminating red tide. This technology sprays magnesium oxide itself to the area where red tide occurs, and quickly removes the plankton that causes red tide. However, it requires a process of firing primary raw materials such as metallic magnesium and magnesium hydroxide to prepare magnesium oxide, which raises the problem of increased manufacturing costs. Moreover, the technique of Patent Document 1 is mainly aimed at extermination of red tide occurring in the surface layer of the ocean.

Patent Literature 2 describes that the death of fish due to a decrease in the oxygen concentration in the ocean is prevented by exterminating red tides that occur around fish preserves. However, the plankton that is the main object of extermination even in this technique is only plankton in the surface layer of the ocean.

JP 2019-55914 A JP 2008-239516 A

INDUSTRIAL APPLICABILITY The present invention makes it possible to spray a microbial control agent that continuously exterminates harmful microorganisms living in water for a long period of time not only in the surface layer of water but also in the water area from the middle layer to the deep layer deeper than the surface layer. A microbicide application system is provided. Also provided is a microorganism extermination method capable of continuously exterminating harmful microorganisms inhabiting water over a long period of time in water areas of different depths, i.e., surface, middle and deep water areas.

The above problems of the present invention have been solved by the following means.
[1]
A microbial control agent spraying system for spraying a microbial control agent in water,
The antimicrobial agent contained in a material with a uniform opening is hung so as to correspond to the depth of the habitat of the microorganisms to be exterminated that live in the water, and the antimicrobial agent is applied to the opening part of the material. a dispersal system for a microbicidal agent passing through and diffusely dispersing into the water.
[2]
The antimicrobial agent application system according to [1], wherein the antimicrobial agent contains smectite.
[3]
The microbial control agent application system according to [2], wherein the smectite includes at least one of calcium-type smectite, sodium-type smectite, and activated smectite.
[4]
[3], wherein the material with uniform openings is a net, and the antimicrobial agent is dispersed and dispersed continuously for 10 hours or longer into the water through the openings of the net. antimicrobial spraying system.
[5]
The antimicrobial agent spraying system according to any one of [1] to [4], wherein the antimicrobial agent contains an acid-treated smectite or a mixture of smectite and an aluminum source.
[6]
The antimicrobial agent according to any one of [2] to [5], which is a powder in a dry state, including those having a particle size that passes 75%/200 mesh based on Tyler's sieve. scatter system.
[7]
The antimicrobial agent spraying system according to any one of [2] to [5], wherein the antimicrobial agent is kneaded with water.
[8]
The antimicrobial agent spraying system according to [7], wherein the antimicrobial agent can change its shape as needed.
[9]
The system for spraying a microbial control agent according to any one of [1] to [8], wherein the uniform opening of the material has an opening of 70 to 510 μm.
[10]
The system for spraying the antimicrobial agent according to [7] or [8], wherein the uniform opening of the material has an opening of 400 μm or more.
[11]
The antimicrobial agent spraying system according to any one of [1] to [10], wherein the material containing the antimicrobial agent is suspended movably in the water.
[12]
The antimicrobial agent spraying system according to [11], wherein the material containing the antimicrobial agent is suspended so as to be movable in the water depth direction in accordance with the diurnal vertical movement of the microorganisms.
[13]
The antimicrobial agent spraying system according to any one of [1] to [12], wherein the antimicrobial agent spraying system is used for exterminating red tide-causing plankton.
[14]
A method for exterminating microorganisms living in water, comprising:
A microbial control agent contained in a material with uniform openings is suspended in the water in the habitat of the microorganisms to be exterminated or in the vicinity thereof, and the microbial control agent is passed through the openings of the material. A method for exterminating microorganisms, comprising diffusely spraying into the water.
[15]
The method for exterminating microorganisms according to [14], wherein the antimicrobial agent is moved in the water depth direction in accordance with the vertical movement of the microorganisms to be exterminated.
[16]
A method for cultivating fish and shellfish, comprising:
Using the microbial control agent spraying system according to any one of the above [1] to [13], the microbial control agent is diffusely sprayed on or around the fish and shellfish farming water area, Seafood farming method.

According to the antimicrobial agent spraying system of the present invention, the antimicrobial agent contained in a material having a uniform opening is suspended in water corresponding to the depth of the habitat of the microorganisms to be exterminated. Pesticides (particulates thereof) can be diffusely dispersed in water. At this time, it is also possible to diffusely spray the antimicrobial agent gradually into the water from the opening of the mesh, so long-term spraying becomes possible. For example, continuous application for 24 hours is possible. For this reason, for example, it is sufficient to replenish the antimicrobial agent once a day, and the working efficiency of the antimicrobial effect can be significantly improved.
According to the method for exterminating microorganisms of the present invention, the antimicrobial agent contained in a material having uniform mesh openings is suspended in the habitat of microorganisms to be exterminated in water, and fine particles of the antimicrobial agent are diffusely sprayed in water. can continue. For this reason, it is possible to spray the microbial control agent for a long time in the habitat of the microorganisms to be exterminated, and the microbial control agent can be replenished, for example, once a day. The efficiency of spraying work can be significantly improved. In addition, since it becomes possible to spray the antimicrobial agent corresponding to the water depth of the habitat of the microorganisms to be exterminated, the antimicrobial agent can always be sprayed to the habitat.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a cross-sectional view schematically showing a preferred embodiment of a system for spraying a microbial control agent according to the present invention; It is a graph showing the relationship between the diffusion release rate and the stirring time in the diffusion release test of acid clay in artificial seawater. 4 is a graph showing the relationship between the diffusion release rate and the stirring time in the diffusion release test of Ca-montmorillonite in artificial seawater. 1 is a graph showing the rate of eradication of Karenia mikimotoi for each sample of microbial control agent in seawater.

A preferred embodiment of the antimicrobial spraying system according to the present invention will be described below. In the antimicrobial agent spraying system, the antimicrobial agent contained in a material with uniform opening (uniform) is hung so as to correspond to the depth of the habitat of the microorganisms to be exterminated in water, and the antimicrobial agent is applied. It is sprayed in the water. A detailed description will be given below with reference to FIG. 1 and the like.

As shown in FIG. 1, the antimicrobial agent spraying system 10 applies the antimicrobial agent 21 contained in a net 11 made of a material with uniform openings to a habitat 32 of microorganisms to be exterminated in water 31. , and the fine particles (not shown) of the antimicrobial agent 21 are passed through the openings of the material and continuously sprayed into the water 31 . By adjusting the length of this rope 15, it becomes possible to send the antimicrobial agent to deep water or to distribute it to the surface layer of the water.

The net 11, which is made of a material with uniform mesh openings, is made of resin such as polyethylene, vinyl chloride resin, polyurethane, polyamide, etc., having water resistance, preferably seawater resistance. The net is preferably configured, for example, like a bag. It is preferable that the opening of the bag be openable and closable. For example, it is preferable that the opening of the bag is provided with a chuck capable of opening and closing the opening and closing the bag. Alternatively, the net may be configured in the form of a drawstring bag. In this case, the drawstring bag is preferably closed by squeezing and tying the opening of the drawstring bag. Depending on the size of the drawstring bag, the means for tying may include the above-mentioned resin cords, ropes, chains, rubber bands (for example, made of chloroprene rubber), zippers, etc., which are resistant to erosion by seawater.
The opening of the mesh is uniform throughout, and depending on the size (for example, particle size) of the fine particles of the antimicrobial agent, when fine particles of clay minerals such as smectite are used as the antimicrobial agent, the mesh size is 300 to 300. It can be 600 μm, preferably 50 to 200 μm. In addition, it is preferable that the mesh opening is 90 to 280 μm for the powdered antimicrobial agent.
The microbial control agent for the above-mentioned open-mesh net is preferably 50% by mass or more, in a dry state, with a particle size that passes through a Tyler sieve with the following "opening ratio (%) / mesh". More preferably 70% by mass or more, still more preferably 80% by mass or more, and still more preferably 90% by mass or more. That is, it is preferable to contain particles having a particle size that passes through a Tyler sieve with an opening ratio (%)/mesh of 75%/200 mesh in the above preferred amount. It is also preferred to include a particle size that passes through a Tyler sieve of 70%/250 mesh in the above preferred amount. It is also preferred to include a particle size that will pass through an 80%/250 mesh Tyler sieve in the above preferred amount. It is also preferred to use a particle size that passes through a Tyler sieve of 80%/200 mesh. The dry state means that the moisture content is 10% by mass or less.
If the antimicrobial agent has such a particle size, fine particles of the antimicrobial agent can be diffused and released gradually into the water through the openings of the mesh to be dispersed. Further, by controlling the amount, properties, etc. of the antimicrobial agent to be put into the net, fine particles of the antimicrobial agent can be continuously put into water for a long period of time (for example, 10 hours or longer, preferably 15 hours or longer, more preferably 20 hours or longer). can be disseminated. That is, it is possible to continuously diffusely spray the microbicidal agent into the water (from the inside to the outside of the net) at an approximately constant rate.

The above-mentioned opening and aperture ratio can be obtained as follows.
Let A (mm) be the mesh opening, M be the mesh (Tyler), d (mm) be the wire diameter of the thread or wire constituting the net 11, and ε (%) be the opening ratio of the openings 12 of the net 11.
Eye opening: A = (25.4/M) - d
Aperture ratio: ε = (A / (A + d)) ² × 100 (%)
It can be expressed as.

For example, to allow 24 hour continuous application of a microbicidal agent, e.g., as microbicidal agent 21 (e.g., smectite), 75% open per Tyler sieve/mesh/pass through a 200 mesh sieve A predetermined amount of particles having a particle size may be suspended in water (in the sea) by enclosing it in a net having an opening of preferably about 70 to 510 μm to 90 to 280 μm.

The antimicrobial agent 21 is preferably a product obtained by hydrating and kneading a hydrated clay mineral (preferably containing smectite, more preferably containing montmorillonite). For example, the water content of the clay mineral is preferably 30 to 50% by mass, more preferably 35 to 45% by mass, from the viewpoint of sustained release of the antimicrobial agent.
In the microbial control agent kneaded with water (for example, water content of 35 to 50% by mass), for example, smectite powder (smectite (for example, bentonite or white clay) containing water and kneaded with water, diffusion release is suppressed, so the opening is 250 μm or more, further 300 μm or more, further 400 μm or more, further 450 μm or more, and further can be used even if the net 11 has a large opening of 500 μm or more (for example, about 503 μm).In this case, the opening is preferably 800 μm or less, and preferably 650 μm or less. Regarding the shape of the pesticide, it can be modified according to the application, such as a spherical shape or a block shape.
That is, the antimicrobial agent containing smectite that has been kneaded with water as described above can be used even in a mesh with a significantly larger mesh size than the powder of the antimicrobial agent that has passed through the Tyler sieve before being kneaded with water. Become. For example, it is possible to use a net with a mesh size about 5 to 10 times larger than the particle size of the microbicide powder that passes through the Tyler sieve.
Since a net with a large opening can be used, there is an advantage that clogging of the net with clay can be prevented.

Preferably, the antimicrobial agent comprises a smectite. The smectite preferably comprises montmorillonite, more preferably montmorillonite. In the present invention, bentonite and/or clay are preferably used as the smectite or montmorillonite, more preferably bentonite and/or acid clay, and even more preferably bentonite. The smectite content in the antimicrobial agent is preferably 50% by mass or more, more preferably 60% by mass or more, still more preferably 70% by mass or more, and can be 80% by mass or more. The upper limit of the smectite content in the antimicrobial agent is not particularly limited, and may be 100% by mass, and is usually 99% by mass or less. The content of montmorillonite in the antimicrobial agent is preferably 50% by mass or more, more preferably 60% by mass or more, still more preferably 70% by mass or more, and can be 80% by mass or more. The upper limit of the content of montmorillonite in the antimicrobial agent is not particularly limited, and may be 100% by mass, or usually 99% by mass or less.

The smectite preferably contains at least one of calcium-type smectite, sodium-type smectite, and activated smectite.
The Ca-type smectite is preferably montmorillonite with a high calcium content: (Na, Ca) _0.33 (Al, Mg) ₂ Si ₄ O ₁₀ (OH) _{2.nH 2 O.}
Na-type smectite is preferably sodium-rich montmorillonite: (Na, Ca) _0.33 (Al, Mg) ₂ Si ₄ O ₁₀ (OH) _{2.nH 2 O.}
Activated smectite is artificially converted to sodium form by adding several mass % of sodium carbonate to Ca-type smectite.

The antimicrobial agent 21 also preferably contains smectite treated with an acid (acid treated product). For example, smectite treated with hydrochloric acid or sulfuric acid can be used. For example, in the treatment using dilute hydrochloric acid, 30 to 30 to 30% smectite is added to a 0.2 to 3 mol% aqueous solution (preferably 0.5 to 2 mol% aqueous solution) of hydrogen chloride at 15 to 30°C (preferably 20 to 25°C). It can be obtained by soaking for 300 minutes (preferably 50 to 200 minutes), washing with water, and drying. Thereby, an acid-treated smectite can be obtained.
Alternatively, in the treatment using dilute sulfuric acid, 30 to 300% smectite is added to 0.2 to 3 mol% sulfuric acid (preferably 0.5 to 2 mol% sulfuric acid) at 15 to 30°C (preferably 20 to 25°C). It is obtained by immersing for minutes (preferably 50 to 200 minutes), washing with water, and drying.
In this way an acid-treated smectite can be obtained. The use of acid-treated smectite has the effect of promoting the elution of aluminum ions (Al ³⁺ ) in smectite.

Alternatively, the antimicrobial agent 21 may contain a mixture of smectite and an aluminum source (for example, aluminum chloride, aluminum sulfate (including alum), polyaluminum chloride, etc.) (mixture of smectite and aluminum source). preferable. For example, when aluminum chloride is mixed with smectite, the amount of aluminum chloride in the mixture is preferably 5% by mass to 50% by mass, more preferably 5% by mass to 30% by mass, and more preferably 10% by mass to It is more preferable to make it 20% by mass. When aluminum sulfate is mixed, the amount of aluminum sulfate in the mixture is preferably 5% to 50% by mass, more preferably 5% to 30% by mass, and 10% to 20% by mass. It is more preferable that When the aluminum sources are mixed in this way, when the antimicrobial agent is sprayed into the water, the aluminum ions (Al ³⁺ ) destroy the cells of the microorganisms (phytoplankton) in the water, and the fine particles of the antimicrobial agent destroy the cells. By enveloping and submerging the destroyed microbes, the microbes targeted for eradication can be removed from the desired underwater area.

Microorganisms in the present invention mean phytoplankton, zooplankton, bacteria and the like.
Specifically, according to the Japanese Society of Microbial Ecology, microorganisms include bacteria, fungi, viruses, microalgae (phytoplankton, zooplankton, etc.), and protozoa (amoeba, paramecia, etc.). Phytoplankton is a plankton that has pigments and performs photosynthesis, and includes, for example, plankton that causes the generation of red tide, blue-green algae, and the like. Zooplankton are plankton that feed. In this specification, plankton that performs both photosynthesis and feeding is included in phytoplankton.

The phytoplankton includes, for example, the genus Schattnera, the genus Carenia, and the genus Cochlodinium, as red tide-causing plankton.
The shattonella genus appears near the surface of the sea during the day for photosynthesis. For example, it is known that during the daytime, photosynthesis is performed in the surface layer at a depth of 5 m or less, and at night, it moves up to a depth of 10 m and absorbs nutrients by diurnal vertical migration.
The genus Carenia appears and proliferates in water depths around 5 to 7 m during the day for photosynthesis. It is known to undergo significant diurnal vertical migration at night, reaching depths greater than 10-20m. In particular, Karenia mikimotoi, which is a red tide-causing plankton, is known.
Cochlodinium is known to appear near the sea surface during the day for photosynthesis.
Some of the phytoplankton described above begin to descend in the water depth direction in the afternoon even during the daytime, and it cannot necessarily be said to have phototaxis.

Other phytoplankton include, for example, the genus Alexandrium and the genus Dinophysis, which are causative plankton for shellfish poisoning. The former becomes paralytic shellfish poison and the latter becomes diarrhea shellfish poison when shellfish take in these substances together with seawater and accumulate them in their bodies.

Examples of bacteria include Escherichia coli, Salmonella, and the like.

The term "water that is the habitat of microorganisms" includes sea water, brackish water, and fresh water. Red tides and blue-green algae caused by phytoplankton occur in all water areas. The present invention can be effectively used for their extermination.

The antimicrobial agent spraying system of the present invention is effective for extermination of microorganisms living in water as described above, and is particularly effective for extermination of red tide.
Red tide is caused by, for example, a large amount of phytoplankton occurring in the ocean enriched by natural disasters such as landslides and heavy rains. When a red tide occurs, mass mortality of fish and shellfish often occurs in water areas covered by red tide (not only seawater but also freshwater and brackish water). For example, mass mortality of fish and shellfish in farms due to red tide is mainly due to suffocation. Suffocation is caused by a large amount of dissolved oxygen in the seawater being consumed during the process of respiration of the phytoplankton itself and the active decomposition of the dead plankton by bacteria. Therefore, in order to exterminate red tide, it is important not only to exterminate the phytoplankton that causes red tide, but also to remove the dead phytoplankton from the habitat of fish and shellfish.
In addition, since the red tide-causing plankton comes from offshore to the shore and from the seabed to the sea surface, the effect of the red tide arriving around the cage can be reduced by installing the fine particle pesticide spraying system of the present invention in advance. It can be prevented from happening.

According to the microbial control agent spraying system 10, even if the microbial control agent is placed in the water, the microbial control agent is diffused and released into the water at once because the microbial control agent is contained in the material with the uniform mesh opening. The microparticles that make up the antimicrobial agent are gradually diffused and released into the water. In particular, by using the net 11 having the above-described open area ratio and mesh, the fine particles of the antimicrobial agent 21 can be diffused and released into the water at a constant speed and dispersed. By controlling the mesh and opening ratio of the net with uniform mesh openings, it becomes possible to release and diffuse the antimicrobial agent into the water in a controlled manner. That is, the amount of microbicidal agent released from the mesh per unit area can be controlled.

For this reason, it becomes possible to prolong the spraying time of the antimicrobial agent, so that the antimicrobial agent can be continuously dispersed and released into water for, for example, 24 hours. In this way, it is possible to secure a long period of time, for example, 24 hours, during which the antimicrobial agent is sprayed in water. As a result, the frequency of replacement of the antimicrobial agent can be reduced to, for example, once a day, making it possible to significantly improve work efficiency.
In addition, since it is possible to install the antimicrobial agent according to the depth of water where microorganisms live, it becomes possible to exterminate microorganisms to be exterminated in water all day long.
Also, for example, when installing the antimicrobial agent around a water area (for example, a fish tank) to be exterminated of microorganisms, it is effective to install the antimicrobial agent on the side from which the tide flows. It is also effective to install the tank at a certain distance from the fish tank in a plan view in consideration of the diffusion area of the antimicrobial agent in the water.

In addition, the antimicrobial agent is included in a net and suspended in water (for example, in seawater), so that the antimicrobial agent can be moved and installed according to the habitat depth of the microorganism against the microorganisms that move vertically during the day. becomes possible, and it becomes possible to exterminate microorganisms throughout the day. Therefore, it is possible to enhance the efficiency of eradicating microorganisms.

In addition, by disposing the antimicrobial agent in deep water positions, it is possible to prevent invasion of microbes to be exterminated from deep water parts of the fish tank. In this way, by distributing the microbial control agent in various water depths from the deep zone to the surface zone, it becomes possible to protect the entire cage from microorganisms to be exterminated throughout the entire range of water depths in the cage. This makes it possible to enhance the safety of the fish and shellfish in the cage. This eliminates the need to move the cage to a deeper water depth when red tide occurs, for example, in the middle layer area, and it becomes possible to protect against red tide at the water depth where red tide occurs.
In the above explanation, we have explained about fish cages, but also in the water areas of raft-type hanging culture and cage-type hanging culture, by distributing the antimicrobial agent corresponding to each water depth, it is possible to exterminate the microorganisms to be exterminated in the same way. can.

In one embodiment of the present invention, among smectites, 5 to 30% by mass of an aluminum source (for example, aluminum chloride (including polyaluminum chloride), alum, etc.) is added to the Na-type, Ca-type and active forms of montmorillonite. Sprinkle a uniformly mixed antimicrobial agent into the water. As a result, the Al ³⁺ ions destroy the cell membranes of plankton, and the montmorillonite captures and precipitates the plankton whose cell membranes have been destroyed, and exterminates them.
Due to this precipitation, bacteria that try to decompose plankton whose cell membrane has been destroyed will not gather, so the lack of oxygen in the water due to bacterial activity will not occur, and the biochemical oxygen demand (the amount of dissolved oxygen in the water) will increase. decrease in
Also, since montmorillonite is a natural product, the cost of the pesticide can be kept low.

Next, the method for exterminating microorganisms of the present invention for exterminating microorganisms that live in water and are targeted for extermination will be described below.
In the method for exterminating microorganisms of the present invention, the antimicrobial agent contained in a material having uniform mesh openings is suspended in or near the habitat of microorganisms to be exterminated in water, and fine particles of the antimicrobial agent are dispersed in the water. diffusely released to For example, when the phytoplankton to be exterminated is Karenia mikimotoi and a microbial control agent in which aluminum chloride is mixed with bentonite containing montmorillonite as a main component, the concentration of the microbial control agent in water is about 500 to 1000 ppm. Shows extermination effect. The concentration of the antimicrobial agent in water is preferably 500-8000 ppm, more preferably 500-3000 ppm, and more preferably 800-2000 ppm. By having the above concentration, it is possible to exterminate microorganisms to be exterminated. If the concentration is too low, the extermination effect may be insufficient. On the other hand, if the concentration is too high, a sufficient extermination effect can be obtained, but the extermination cost increases.

Further, by using the system for spraying the antimicrobial agent of the present invention, the antimicrobial agent can be moved in the water depth direction in accordance with the diurnal vertical movement of microorganisms to be exterminated. The movement of the antimicrobial agent in the water depth direction may be performed by placing the antimicrobial agent in the above-mentioned bag-like net, suspending it from a rope or the like, and manually ascending and descending, or time-controlled ascending and descending. It may be performed automatically (for example, electrically) using a winch or the like that can be used. As a result, the antimicrobial agent can be sprayed in the extermination water area corresponding to the water area inhabited by the microorganisms to be exterminated. That is, by spraying the antimicrobial agent in advance in a water area in which microorganisms to be exterminated move, when the microbes to be exterminated move to the sprayed water area, the microorganisms to be exterminated can be exterminated. In this way, it is possible to exterminate microorganisms to be exterminated not only in the surface area but also in the middle layer area and the deep layer area.

Next, an aquaculture method for cultivating fish and shellfish in water will be described below.
Typically, aquaculture waters are waters in cages or waters with mollusks suspended on rafts. It is preferable to apply the method for cultivating fish and shellfish of the present invention to these water areas. That is, it is preferable to spray the antimicrobial agent in a water area for cultivating fish and shellfish or around the water area for cultivating fish and shellfishes using the antimicrobial agent spraying system described above. It should be noted that the surrounding area of the aquaculture area is preferably determined as appropriate in consideration of the tidal current, wind direction, etc. in the aquaculture area.

In the past, pesticides were sprayed toward the red tide when the red tide approached the farming cages and farming rafts. However, by using the microbial control agent spraying system of the present invention, at the stage when red tide occurrence is predicted, the microbial control agent can be suspended around the cage 2 to 3 days before. can be disseminated. Moreover, by utilizing the sustained release property of the antimicrobial agent, it is possible to continuously spray it in water for 24 hours or longer. Therefore, when the red tide flows around the fish tank, the red tide can be reliably exterminated from the fish tank. Moreover, since the antimicrobial agent is suspended in the water, it can be moved in the water depth direction. Therefore, by moving the microbial extermination agent in the water depth direction in response to the vertical movement of the microbes (phytoplankton) that move vertically during the day, the inhabitation of the microbes to be exterminated in the water can be maintained regardless of day or night. area can be sprayed with antimicrobial agent.

Further, by using the microbial control agent kneaded with water, the diffusion release amount becomes moderate, and the diffusion release amount becomes easy to control. In addition, by appropriately selecting the opening ratio and mesh of the net, the amount of diffusion release of the antimicrobial agent can be controlled, and the sustained release of the antimicrobial agent can be ensured. In addition, the use of a water-mixed antimicrobial agent results in a gentler and more controllable diffusional release of the antimicrobial agent.

According to the method for cultivating fish and shellfish of the present invention, the method for exterminating aquatic microorganisms of the present invention can be applied. For example, 10 to 20 kg of the antimicrobial agent is placed in a mesh bag having a mesh size of 300 to 500 μm so that the effective concentration of the antimicrobial agent is 1000 ppm or more, and the bag is closed. Then, it is effective to suspend the mesh bags containing the antimicrobial agent at intervals of 2 to 5 m, preferably at a water depth of 1 to 20 m, more preferably 5 to 15 m, and even more preferably 5 to 10 m. The effective concentration is defined as the concentration of the antimicrobial agent in seawater within 1 to 2 m around the mesh bag containing the antimicrobial agent.
By doing so, the effect of exterminating harmful microorganisms such as red tide from the surroundings of the fish tank can be obtained continuously for a long time. As a result, microorganisms that cause red tide can be exterminated from around the fish tank at all times, and fish and shellfish farming can be protected from threats such as red tide. This will improve the productivity of aquaculture.

The present invention will now be described in more detail based on the following examples. The present invention is by no means limited by these examples.

<Test Example 1>: Montmorillonite diffusion release test in artificial seawater Figures 2 and 3 show the results of this test.
The outline of the test is as follows. A cylindrical container with a capacity of 1 L was used as the stirring container. Artificial seawater (36 g/L) was placed in the container. Artificial seawater was prepared by dissolving 36 g of Daigo artificial seawater SP for marine microalgae manufactured by Nihon Pharmaceutical Co., Ltd. in 1 L of distilled water. As a result, the salt concentration was 3.6% by mass.
The microbial control agent contains 100 g of acid clay with a water content of 8 to 12% (particle size that passes 80%/200 mesh in Tyler's sieve) in terms of anhydrous mass, and potassium aluminum sulfate (potassium) as an aluminum source. A sample 1 was prepared by mixing 10 g of alum (also called alum). In addition, sample 2 was prepared by mixing 100 g of Ca-type montmorillonite (particle size that passes 75%/200 mesh in a Tyler sieve) in terms of anhydrous mass and 10 g of potash alum. Therefore, samples 1 and 2 were both 110 g.
Samples 1 and 2 were each wrapped in four types of polyethylene (PE) nets having uniform mesh openings of 503 μm, 280 μm, 90 μm and 76 μm. The mesh was cut into squares of 120 to 150 mm square on each side. The net was made into a purse-like bag, the sample was placed therein, and the opening of the purse-like net was tied up with a rubber band.
Furthermore, samples (water kneading) (water content: 39%) were also prepared by adding 70 g of water to the above samples 1 and 2 and kneading them with water. Sample 1 has an opening of 503 μm, and sample 2 has an opening of 90 μm and 503 μm. A polyethylene mesh cut into squares with sides of 120 to 150 mm is made into a drawstring bag and kneaded with water. 180 g of was put in, and the opening of the purse-like net was tied up with a rubber band.
They were suspended so that the top of the mesh bag was 5-7 cm below the surface of the artificial seawater in a 1 L container so that the entire bag was immersed in separate artificial seawater. This is the depth at which the sample does not touch the rotating blades of the stirrer. Using a stirrer (manufactured by Sintokagaku Kogyo Co., Ltd., trade name: Three-One Motor), artificial seawater was stirred at a rotation speed of 30 rpm assuming waves in the ocean.
Then, the diffusion release rate (%) with respect to the stirring time was determined for each sample.
The results are shown in FIG. 2 (Sample 1) and FIG. 3 (Sample 2). The results of samples obtained by kneading samples 1 and 2 with water are also shown in FIG. 2 (sample 1) and FIG. 3 (sample 2).

The diffusion release rate (%) was calculated by 100-([mass of clay remaining in the mesh (converted to dry mass)]/[mass of charged clay (converted to dry mass)]) x 100 (%). Drying in this case means that the moisture content is 1% or less. Since the denominator in the above formula is constant irrespective of the net, the greater the amount of clay released into the artificial seawater, the greater the diffusion release rate. Therefore, it was found that 50% or more of the antimicrobial agent remained on the inside of the net with a mesh size of less than 280 μm even after being submerged in water for 24 hours (one day). In addition, it was found that the diffusion release amount can be controlled by opening the opening as shown in FIG.

In addition, if kneaded with water in advance (clay moisture content of 39% by mass), moderate sustained release properties can be achieved even with an opening of 503 μm, and in this test, it was found that the antimicrobial agent could be continuously supplied for 24 hours.

<Test Example 2>: Extermination test for Karenia mikimotoi in seawater FIG. For samples 3 and 4, Ca-type bentonite or activated bentonite (Ca-type montmorillonite added with soda ash to make Na-type (75%/200 mesh in Tyler sieve) in 1 to 2 mol/L hydrochloric acid or sulfuric acid )) was immersed for 1 hour or more, filtered and dried to obtain a dry product (acid-treated Ca-Bt), and further washed with distilled water (washed). As sample 5, a sample (neutralized) obtained by neutralizing the dried product (acid-treated Ca-Bt) with a 1 mol/L sodium hydroxide aqueous solution was used. For Samples 6 to 15, powdery Ca-bentonite and aluminum chloride hexahydrate were weighed so as to have the formulation shown in Table 1, and the powders were uniformly mixed and used as each sample. .
Karenia mikimotoi was diluted in filtered seawater (water temperature 20° C.) to 10000 to 30000 cells/mL. A microbial (red tide) repellent was sprayed so that the concentration was 500 to 5000 ppm with respect to the amount of filtered seawater. The concentration in Table 1 indicates the concentration of the red tide exterminator in seawater.
The extermination rate was determined by the following formula.
[Removal rate] = {([Number of Karenia mikimotoi cells in 1 mL of filtered seawater before spraying red tide pesticide-[Number of Karenia mikimotoi cells in 1 mL of solution after spraying red tide pesticide]) / [Before spraying red tide pesticide Number of Karenia Mikimotoi cells in 1 mL of filtered seawater]} × 100%
The number of cells of Karenia mikimotoi was measured as follows.
Five minutes after the application of Karenia mikimotoi, 1 mL of filtered seawater supernatant was collected, and the number of cells in a plankton counter (Matsunami plankton counter MPC-2000) was counted using an optical microscope (OLYMPUS BX50).

In Table 1, Ca-Bt represents Ca-type bentonite.

The red tide extermination effect of the red tide extermination agent is as shown in FIG. 4 and Table 1, and extermination effect was observed for all samples. In particular, the sample in which aluminum chloride hexahydrate and Ca-type bentonite were combined showed a good extermination effect even when the concentration of the red tide extermination agent was low.
By appropriately kneading these samples with water, continuous spraying for a desired long period of time became possible.

10 Microbial disinfectant spraying system 11 Net (material)
12 opening 15 rope 21 antimicrobial agent 31 water 32 microbial habitat

Claims (16)

A microbial control agent spraying system for spraying a microbial control agent in water,
The antimicrobial agent contained in a material with a uniform opening is hung so as to correspond to the depth of the habitat of the microorganisms to be exterminated that live in the water, and the antimicrobial agent is applied to the opening part of the material. a system for dispersing a microbicide that passes through the water and is diffusely dispensed into the water. 2. The antimicrobial distribution system of claim 1, wherein the antimicrobial agent comprises a smectite. 3. The microbicidal agent application system according to claim 2, wherein the smectite comprises at least one of a calcium-type smectite, a sodium-type smectite, and an activated smectite. 4. The method according to claim 3, wherein the material having uniform openings is a net, and the antimicrobial agent passes through the openings of the net and is dispersed and dispersed continuously into the water for 10 hours or longer. antimicrobial spraying system. The antimicrobial agent application system according to any one of claims 1 to 4, wherein the antimicrobial agent comprises an acid-treated smectite or a mixture of smectite and an aluminum source. The antimicrobial agent according to any one of claims 2 to 5, wherein the antimicrobial agent is a powder in a dry state, including those having a particle size that passes 75%/200 mesh based on Tyler's sieve. scatter system. The system for spraying the antimicrobial agent according to any one of claims 2 to 5, wherein the antimicrobial agent is kneaded with water. 8. The microbicidal distribution system of claim 7, wherein the microbicidal can change shape as desired. The system for spraying the antimicrobial agent according to any one of claims 1 to 8, wherein the material having a uniform opening has an opening of 70 to 510 µm. 9. The system for spraying the antimicrobial agent according to claim 7 or 8, wherein the material having uniform mesh openings has a mesh opening of 400 [mu]m or more. The antimicrobial spraying system according to any one of claims 1 to 10, wherein the material containing the antimicrobial agent is suspended movably in the water. 12. The antimicrobial agent spraying system according to claim 11, wherein said material containing said antimicrobial agent is suspended so as to be movable in the water depth direction in accordance with the diurnal vertical movement of said microorganisms. 13. The microbicide spraying system according to any one of claims 1 to 12, wherein the microbicide spraying system is used for exterminating red tide-causing plankton. A method for exterminating microorganisms living in water, comprising:
A microbial control agent contained in a material with uniform openings is suspended in the water in the habitat of the microorganisms to be exterminated or in the vicinity thereof, and the microbial control agent is passed through the openings of the material. A method of combating microorganisms comprising diffuse application into water. 15. The method for exterminating microorganisms according to claim 14, wherein the antimicrobial agent is moved in the water depth direction in accordance with the vertical movement of the microorganisms to be exterminated. A method for cultivating fish and shellfish, comprising:
Fish and shellfish, comprising diffusely spraying the microbial control agent in or around the culturing water area of the fish and shellfish using the microbial control agent spraying system according to any one of claims 1 to 13. aquaculture methods.

Images