JP6860764B2 - Aquaculture method and aquaculture equipment - Google Patents

Description

The present invention relates to aquaculture methods and aquaculture facilities in aquaculture facilities where fish and shellfish are cultivated by stored breeding water such as aquaculture tanks and fishponds.

The technique of commercially cultivating edible fish and shellfish in aquaculture tanks and aquaculture ponds installed on land is well known as so-called aquaculture, and is applied to various fish species such as eels, tiger puffer fish, chars, yamame trout, and butterfly sharks. .. In order to reduce the cost of aquaculture and secure profits, it is necessary to increase the number of individuals per breeding water, that is, the individual density to some extent, but if the individual density is excessively high, there is a risk of getting sick or dying. There is. Therefore, there is a commercially appropriate range of individual densities. The standard solid density in aquaculture, that is, the standard density of aquaculture varies depending on the type of fish and shellfish, but for example, 70 to 130 animals / m ³ for eels and 10 to 30 animals / m ³ for yamame trout. It is common to do. The density of such standard aquaculture individuals is excessively large compared to the density of solids of the same species inhabiting natural seas, rivers, ponds, and the like. Therefore, an aeration device for supplying the oxygen required for breeding water is provided. In addition, sediments such as feces are collected from the bottom of the pond every day and discarded. Alternatively, a filtration device is provided to remove feces and leftover food from the breeding water.

By the way, even in aquaculture on land, a predetermined amount of breeding water is appropriately drained to the outside and fresh water is replenished from the outside to maintain a fresh state, but if the frequency of drainage and replenishment is high, the temperature of the breeding water changes. Therefore, the energy cost increases because the water is heated and cooled to a water temperature suitable for the target fish species. In order to reduce energy costs, it is necessary to avoid draining breeding water or to reduce the frequency of drainage, if any. However, in this case, there is a problem that the concentration of nitrate nitrogen becomes high. Nitrate nitrogen is produced by the decomposition of proteins contained in the turbidity of breeding water by microorganisms. First, aerobic heterotrophic bacteria produce highly toxic ammonia, which is relatively quickly converted to less toxic nitrite by nitrosomonas nitrifying bacteria. Nitrite is eventually converted to harmless nitrate by nitrifying bacteria belonging to the genus Nitrospira, but the processing capacity of the latter nitrifying bacteria is not so great. Then, the concentration of nitrite tends to increase, and seafood will die. Therefore, in many aquaculture facilities, a predetermined treatment agent for treating nitrate nitrogen is appropriately added, and the breeding water is adjusted so that the concentration of nitrate nitrogen, which is toxic to fish and shellfish, does not increase.

Japanese Unexamined Patent Publication No. 2015-73458 Japanese Unexamined Patent Publication No. 2001-314136 Japanese Unexamined Patent Publication No. 5-115870

Various patent documents have proposed devices that suppress an increase in the concentration of nitrate nitrogen in breeding water without adding a treatment agent. Patent Document 1 describes a water purification device that can also be used for land cultivation and includes a sand filtration device and a bio-purification treatment device. The sand filter is a filter containing a filter medium made of filter sand, and is designed to remove feces and food residue floating in the breeding water. The bio-purification treatment device consists of a container containing an active stone made of bakuhan stone. Air or ozone is supplied to the breeding water as needed, and when such breeding water is supplied to the bio-purification treatment device, nitrifying bacteria of the genus Nitrospira are activated in Maifan stone and nitrite in the breeding water is nitrate. Changes to. This nitrifying bacterium is a so-called obligate aerobic bacterium that requires a large amount of oxygen, but the breeding water contains sufficient oxygen and the bakuhan stone is porous, so that the nitrifying bacterium is sufficiently active. Because it becomes. Therefore, when the water purification device described in Patent Document 1 is used, it is not necessary to add a treatment agent for treating nitrate nitrogen in the breeding water. Alternatively, even if it is added, a small amount is sufficient.

Patent Document 2 describes a filtering device including a first filtering material made of grain-burning charcoal and a second filtering material made of bakuhan stone. It is considered that this filtration device is not a device used for land cultivation but a device used for an ornamental breeding aquarium, but when breeding water is supplied to this filtration device, feces and dust are collected in the first filter medium. Is removed, and nitrate nitrogen is treated by the action of microorganisms in the second filter medium. Patent Document 3 also describes a water treatment device for an ornamental breeding aquarium, and this water treatment device also contains bakuhan stone to treat nitrate nitrogen.

In the onshore aquaculture facility, the breeding water can be maintained at a predetermined water quality even if an aeration device and a filtration device are provided and a treatment agent for treating nitrate nitrogen is appropriately added as in the conventional method. .. Further, even if the treatment agent for nitrate nitrogen is not used, if the water purification device described in Patent Document 1 is provided, the breeding water can be sufficiently maintained at a predetermined water quality. Further, even if the filtration device described in Patent Document 2 or the water treatment device described in Patent Document 3 is used, there is a possibility that the breeding water for aquaculture can be maintained at a predetermined water quality. If any of these methods is adopted, the breeding water in land-based aquaculture can maintain the water quality at a predetermined level even if the frequency of drainage is reduced, and thus the death of fish and shellfish can be prevented. However, even if the death of seafood is prevented, there are other problems to be solved in land aquaculture. The problem is that the rate of growth and the degree of growth of seafood are not always sufficient. For example, eels are released into aquaculture ponds with so-called shirasu fry. Shirasu grows and eventually becomes a blackish discolored state called crocodile, and is called biri, which grows a little further and grows to a body length of 7 to 10 cm. When the billi grows, it becomes about 200 g of adult eel and is shipped. However, in eel farming, there are a predetermined ratio, for example, 10 to 30% of individuals whose growth stops in the state of crocodile or billi. Such individuals rarely grow even after being cultivated for more than a year. Then, such an individual has no choice but to discard it. Even for eels that have grown into adult fish, individuals that do not necessarily grow sufficiently and do not grow at a predetermined rate occur. Therefore, the price will be low. Even when culturing other fish species such as yamame trout, the rate of growth and the degree of growth are not always sufficient. That is, in land-based aquaculture, there is a problem that it takes time to become an adult fish and the cost cannot be reduced.

An object of the present invention is to provide aquaculture methods and aquaculture equipment that solve the above-mentioned problems. Specifically, in aquaculture on land, the growth rate of fish and shellfish can be increased, and the proportion of individuals that stop growing can be reduced as much as possible, thereby reducing the cost required for aquaculture and increasing profits. It is intended to provide aquaculture methods and such aquaculture facilities that can be used.

The present invention targets aquaculture methods for cultivating eels, chars, or yamame trout in stored breeding water in order to achieve the above object. A predetermined amount of crushed bakuhan stone is immersed in the breeding water. It also supplies air containing ozone. ^{Maifan stone is soaked in 35 kg or more per 1 m 3} of breeding water in the case of eel, and 70 kg or more per ^{1 m 3} of breeding water in the case of char or yamame trout. The air containing ozone is supplied from below the bakuhan stone, and the ozone concentration of the breeding water is adjusted to 0.001 to 0.005 ppm.

That is, the invention according to claim 1 is a aquaculture method for cultivating eels, sardines, or yamame in the stored breeding water, in which a predetermined amount of crushed barley stone is immersed in the breeding water and contains ozone. Air is supplied to the breeding water, and the barley stone is ^{soaked in 35 kg or more per 1 m 3} of breeding water in the case of eels, and 70 kg or more per ^{1 m 3} of breeding water in the case of Iwana or Yamame. The supply of air containing ozone is configured as a method for culturing eels, sardines, or yamame, which is characterized in that the ozone concentration of the breeding water is adjusted to 0.001 to 0.005 ppm.
According to the second aspect of the present invention, in the aquaculture method according to the first aspect, the ozone-containing air is supplied from below the bakuhan stone, and the bakuhan stone is exposed to air bubbles containing the ozone. It is configured as a method of culturing eels, chars, or yamame trout, which is characterized by the above.
The invention according to claim 3 is an aquaculture facility for eels, sardines, or yamame that stores breeding water, and a predetermined amount of crushed barley stone is contained in the aquaculture tank or pond of the aquaculture facility. Air containing ozone is supplied to the breeding water while being immersed in the breeding water, and the barley stone is ^{immersed in 35 kg or more per 1 m 3} of the breeding water in the case of eels, and in the case of Iwana or Yamame, the breeding water. An eel, sardine, or yamame that is immersed in 70 kg or more per 1 m ^{3 and} whose supply of air containing ozone is adjusted so that the ozone concentration of the breeding water is 0.001 to 0.005 ppm. It is configured as aquaculture equipment.
According to a fourth aspect of the invention, the aquaculture facility according to claim 3, the air containing the ozone eel, characterized in that it is supplied by air bubbles from below the elvan, char or trout of It is configured as aquaculture equipment.

As described above, the present invention is a aquaculture method for cultivating eels, chars, or yamame trout in stored breeding water, in which a predetermined amount of crushed bakuhan stone is immersed in the breeding water and air containing ozone is bred. It is configured to supply water. Maifan stone is porous and contains minerals. Since air containing ozone is supplied to the breeding water, nitrifying bacteria, which are obligate aerobic bacteria, easily propagate in Maifan stone. This will result in proper treatment of nitrate nitrogen. The present invention is configured such that Maifan stone is ^{soaked in 35 kg or more per 1 m 3} of breeding water in the case of eel, and 70 kg or more is soaked in 70 kg or more per ^{1 m 3} of breeding water in the case of char or yamame trout. The supply of air containing is adjusted so that the ozone concentration of the breeding water is 0.001 to 0.005 ppm. The amount of such bakuhan stone in the breeding water is unthinkable in the past, and it can be said that it is an excessive amount only for the purpose of treating nitrate nitrogen. However, immersing a large amount of bakuhan stone in breeding water under a predetermined ozone concentration in this way has the effect of promoting the growth of eels, chars, or yamame trout, as revealed by the experiments described later. Be done. Not only will the growth rate be faster, but the size of the adult fish will be uniform and larger. Therefore, the cost required for aquaculture can be reduced, and high profits can be obtained. According to another invention, ozone-containing air is supplied from below the bakuhan stone so that the bakuhan stone is exposed to bubbles in the ozone-containing air. Oxygen can be efficiently supplied to the nitrifying bacteria that propagate in Maifan stone, and the effect of increasing the nitrifying ability can be obtained.

It is a front view which shows the aquaculture equipment which concerns on embodiment of this invention.

The present embodiment will be described. The aquaculture facility 1 according to the embodiment of the present invention can be used for any kind of seafood, but in the present embodiment, it is intended for eel farming. That is, the aquaculture facility 1 according to the present embodiment comprises a eel farm. As shown in FIG. 1, the aquaculture facility 1 is roughly composed of a pond 2 in which breeding water is put and eels are bred, a filtration device 3 for circulating and filtering the breeding water in the pond 2, and the like. .. The side and bottom of the pond 2 are made of concrete and are filled with a sufficient amount of breeding water. The filtration device 3 in the present embodiment includes a pressure vessel 5 and a filter medium 6 contained in the pressure vessel 5, and the filter medium 6 starts from the pebbles layer 7, the gravel layer 8, and the filter sand layer 9 in this order from the lower layer. Become. That is, in the present embodiment, the filtration device 3 is configured as a sand filtration device. A predetermined conduit 13 is connected to the top of the pressure vessel 5 from the bottom surface of the pond 3 via a pump 11, and another conduit 14 is connected to the lower part of the pressure vessel and returned to the pond 2. When the pump 11 is driven, the breeding water near the bottom of the pond 2 flows through the pipeline 13 and is supplied to the filtration device 3. The turbidity of the supplied breeding water is filtered out by the filter medium 6. The filtered breeding water flows from the lower part of the filtration device 3 through the pipeline 14 and is returned to the pond 2. That is, the breeding water circulates and is purified by the filtration device 3. The filtration device 3 may be composed of a filtration device using a filter made of a non-woven fabric as a filter material, or may be composed of another type of filtration device, as long as the turbidity of the breeding water can be filtered out. .. Any filtration device can be used as long as the feces contained in the breeding water and the residue of the food can be removed to keep the breeding water clean.

Although not shown in FIG. 1, the aquaculture facility 1 is also provided with a water temperature adjusting device. The water temperature of eels needs to be 20 ° C. or higher, preferably 24-28 ° C., and the water temperature of the breeding water can be adjusted by a dedicated boiler. In this embodiment, a heat pump is adopted so that the water temperature can be adjusted at low cost. The pond 2 is provided with a drainage pipe so that the breeding water can be discharged as needed, and a water supply pipe so that fresh water can be supplied when the breeding water is reduced. Not shown in.

The aquaculture equipment 1 according to the present embodiment is provided with equipment different from the conventional aquaculture equipment. A large amount of active stone 16 made of so-called bakuhan stone and an aeration device 17 that supplies ozone as well as air to breeding water. These will be described.

In a conventional pond of a eel farm, a gravel layer is provided on the bottom surface to a predetermined thickness, and a soil layer is laid on the gravel layer to make it flat. The reason for making it flat is to prevent it from obstructing the flow of breeding water, and to make it easier for feces and residual food to accumulate in the center due to the water flow, making it easier to draw up feces and residual food. Unlike the pond of such a conventional eel farm, the pond 2 of the aquaculture facility 1 according to the present embodiment contains an active stone 16 made of crushed bakuhan stone having a predetermined particle size on the bottom surface thereof. That is, the bottom surface of the pond 2 is not flat. Although this slightly obstructs the flow of breeding water, the effect peculiar to the present invention that the breeding water can be activated can be obtained. Maifan stone is composed of granodiorite or quartz porphyry and has undergone hydrothermal action and weathering action. Maifan stone, which has bean-grain or rice-grain-sized granular crystals and is yellowish-white as a whole, gives the appearance of gathering barley rice. Maifan stone is known to be porous, has an adsorptive effect, and has a large amount of mineral elution. The composition of barley stone varies slightly depending on the origin of barley stone, but it generally contains 65-73% silicon dioxide, 14-17% aluminum oxide, 1-3% ferric oxide, and 0.2-4 magnesium oxide. %, Sodium oxide 2-4%, Potassium oxide 2-5%, Calcium oxide 2-3%, Titanium oxide 0.1-0.5%, Phosphorus pentoxide 0.03-0.22 % Etc. are included. Such bakuhan stone is crushed to a particle size of about 1 to 5 cm, and this is called active stone 16 in the present invention. In the present embodiment, the active stone 16 is divided into net bodies of a predetermined size and immersed in the pond 2. Since it is put in a net body, it can be easily carried out when it is necessary to take out the active stone 16 for maintenance of the pond 2.

By the way, Maifan stone has been known to have an action of purifying breeding water as described with respect to Patent Documents 1 to 3, and is used in breeding aquariums and the like. When used for such purification purposes, Maifan stone is not required in large quantities. In other words, a predetermined amount is sufficient. However, the present inventor uses a large amount of Maifan stone while conducting aquaculture experiments using Maifan stone, and when the amount of Maifan stone used exceeds a certain critical point, the growth of seafood is promoted. I found that it would be effective. That is, it was discovered that the active stone 16 made of bakuhan stone has an effect of promoting the growth of fish and shellfish, that is, an effect of activating the breeding water, in addition to the effect of purifying the breeding water. Therefore, in the aquaculture facility 1 according to the present embodiment, bakuhan stone, that is, active stone 16 is used in a large amount that cannot be considered from the conventional common general technical knowledge. Specifically, the following amounts are used depending on the temperature of the breeding water. When the water temperature suitable for aquaculture is 20 ° C. or higher, such as eel, the active stone 16 is immersed so as to be 35 kg or more per ^{1 m 3 of breeding water, more preferably 50 kg or more.} On the other hand, in the case of cold water with a water temperature of less than 20 ° C, which is suitable for aquaculture, such as char and yamame trout, the active stone 16 is added so as to be 70 kg or more per ^{1 m 3 of breeding water, more preferably 100 kg or more.} Soak. Since the pond 2 according to the present embodiment cultivates eels, the breeding water is warm water, and a large amount of active stone 16 is immersed so as to be 35 kg or more per ^{1 m 3 of the breeding water.}

In the present embodiment, the aeration device 17 is adapted to add ozone having a predetermined concentration to not only air but also air and supply it to breeding water. The aeration device 17 includes a supply unit 19 that generates ozone and mixes it with air to supply the ozone, and a nozzle unit 20 that supplies the air containing ozone into the breeding water in a bubble state. The nozzle portion 20 is composed of a conduit stretched at predetermined intervals along the bottom surface of the pond 2, and a large number of pores are formed in the conduit. When air containing ozone is supplied from the supply unit 19 to the nozzle unit 20 via a predetermined conduit, it is generated as bubbles from the pores of the nozzle unit 20 and mixed into the breeding water from the bottom surface of the pond 2. Will be. The activated stone 16 described above is placed on the nozzle portion 20 in a state of being put in a net body. Therefore, the air bubbles rise upward after touching the active stone 16. If the concentration of ozone is high, it adversely affects fish and shellfish. Therefore, the ozone concentration of the breeding water in the pond 2 should be 0.005 ppm or less, preferably 0.0003 to 0.003 ppm, and more preferably 0. Adjust to 0009 to 0.002 ppm.

In the aquaculture facility 1 according to the present embodiment, eels are bred at a standard aquaculture individual density with respect to eels. That relative amount of water of the breeding water, farming Ensure a 70-130 animals / ^{m 3.} Juvenile eels, that is, shirasu, or juvenile crocodile, are released into pond 2 at a standard farmed population density, and a pump 11 is driven to filter the breeding water. Air containing ozone is supplied to the breeding water from the aeration device 17. Nitrifying bacteria such as Nitrosomonas, which nitrifies ammonia into nitrite, and Nitrospira, which nitrifies nitrite into nitrate, propagate around the active stone 16. The concentration of nitrate nitrogen in the breeding water is suppressed. The breeding water not only suppresses the concentration of nitrate nitrogen, but is also activated by a large amount of active stone 16. This boosts the appetite of eels and promotes eel growth. Generally, it takes about 9 to 15 months for shirasu or crocodile to become an adult eel, but in the aquaculture facility 1 according to the present embodiment, it takes 3 to 6 months to become an adult fish. In addition, the proportion of individuals whose growth stops due to crocodile or billi is greatly reduced, the variation in growth among individuals is reduced, and the growth is uniformly large. This makes it possible to ship high quality eels at an early stage.

An experiment was conducted to confirm that the aquaculture facility 1 according to the present embodiment promotes the growth of seafood.
Experimental method: The following pond A, B, C, and the temperature of the breeding water to 24 to 27 ° C. and discharged 100 animals per breeding water 1 m ³ of the crocodile in each and D, performed several months aquaculture, the state of growth Recorded. The released crocodile used was one that had stopped growing for more than 6 months in a conventional eel farm, that is, one that was originally discarded.
Pond A Immerse 35 kg of active stone 16 per ^{1 m 3 in breeding water and supply air containing ozone.} The ozone concentration of breeding water is 0.001 to 0.002 ppm.
Pond B Immerse 20 kg of activated stone 16 per ^{1 m 3 in breeding water and supply air containing ozone.} The ozone concentration of breeding water is 0.001 to 0.002 ppm.
Pond C Immerse 50 kg of active stone 16 per ^{1 m 3 in breeding water and supply air containing ozone.} The ozone concentration of breeding water is 0.001 to 0.002 ppm.
Pond D Immerse 50 kg of active stone 16 per ^{1 m 3 in breeding water and supply only air.}
Experimental result:
In pond A, after 6 months, 50% of the crocodile grew to over 200 g of eel and 20% grew to 80-200 g of eel. Thirty percent were in a crocodile or bili state.
In pond B, after 6 months, only 10% of the eels grew to 200g or more of eels, but 40% grew to 80-200g of eels and 50% stopped growing in the crocodile or bili state. Was there.
In pond C, after 6 months, 80% of the crocodile grew into eels weighing 200 g or more. 10% of the eels grew to 80-200 g, and 10% stopped growing in the crocodile or crocodile state.
In pond D, aquaculture was carried out for one month, but food consumption was low and crocodile growth was hardly observed. Therefore, after the second month, air containing ozone was supplied to the breeding water so that the ozone concentration became 0.001 to 0.002 ppm. Food consumption increased from the day after the ozone supply, and 70% of the crocodile grew to 200 g or more of eels 5 months later. And 20% of the crocodile grew into 80-200 g of eel. 10% of the plants stopped growing in the crocodile state or in the state of crocodile.
Consideration:
It was found that the growth of crocodile, which had been discarded in the past, is promoted when it is cultivated in a pond in which the active stone 16 is immersed. ^{However, it was found that when the active stone 16 weighs as little as about 20 kg per 1 m 3 of} breeding water, the proportion of growing crocodile is small, but when the active stone 16 exceeds 35 kg, the proportion of growing crocodile increases sharply. It was also found that even if the amount of immersion of the active stone 16 is large, the growth of crocodile is not promoted when ozone is not supplied. Many of the individuals that have grown to over 200 g of eels in ponds A, C, and D have white bellies and dark blue backs, and are of high quality eels that are in very good health compared to black eels. there were.
During the experimental period, the nitrate nitrogen concentration was measured in all of the ponds A to D, but the ammonia was about 0.2 to 1.0 ppm and the nitrite was about 0.2 to 2.5 ppm, which differed depending on the pond. Was not seen. That is, regarding the suppression of the nitrate nitrogen concentration in the breeding water, not only the ponds A, C and D but also the pond B had a sufficient effect.
After the completion of the experiment, the active stones 16 immersed in the ponds A to D were examined, and as a result, no slime was generated on their surfaces, and no algae or the like was observed in any of them. Exposure of bubbles containing ozone may have prevented slime and algae from adhering. Although Maifan stone is porous, it is expected that most of its fine pores did not occlude for a long period of time.
In the filtration device 3, feces and residual food were strained and collected every day, but the amount of feces and residual food strained and collected in ponds A and D was as small as about 1/4 of that in pond B. It is considered that the feces are properly decomposed by a sufficient amount of active stone and ozone. It is also considered that this is because the appetite of crocodile became strong and the amount of residual food decreased.

An experiment was conducted to investigate the effect of different ozone concentrations.
Experimental method: Immerse 50 kg of active stone 16 per ^{1 m 3} of breeding water in ponds E, F, and G, ^{supply air containing ozone, and release 100 crocodile / m 3} each to maintain the health of crocodile for 5 days. Examined.
Ponds E, F, and G were adjusted so that the ozone concentrations in the breeding water were 0.0019, 0.0038, and 0.0077 ppm, respectively.
Experimental result:
Croco was fine in both ponds E and F, and food was sufficiently consumed. On the other hand, in Pond G, several crocodile died and the activity was not active.
Consideration:
It was found that high ozone concentrations affect crocodile. It can be said that the ozone concentration should be 0.005 ppm or less for safety.

An experiment was conducted to confirm that the aquaculture facility 1 according to the present embodiment was effective for fish and shellfish cultivated in cold water.
experimental method:
In each of the following ponds H, I, and J, the temperature of the breeding water was set to 14 to 17 ° C., and air containing ozone was supplied so that the ozone concentration of the breeding water was 0.001 to 0.002 ppm. The breeding water was drained and watered so that 20 to 40% of the total was replaced every day. These ponds H, I, and discharged twenty per breeding water 1 m ³ each 4~5cm of trout and the char to J, performed several months aquaculture was recorded the state of growth.
50 kg of active stone 16 per ^{1 m 3} was immersed in pond H breeding water.
70 kg of active stone 16 per ^{1 m 3} was immersed in pond I breeding water.
Pond J 100 kg of active stone 16 per ^{1 m 3 was immersed in the breeding water.}
Experimental result:
When Yamame and Iwana were landed in each of the ponds H, I, and J after 6 months and the average weight was measured, the average weight of the pond H was 109 g, that of the pond I was 121 g, and that of the pond J was 131 g. The ratios of yamame trout and char that grew to 300 g or more to the total number of yamame trout and char were about 10%, 20%, and 25% in ponds H, I, and J, respectively. Both Yamame and Iwana individuals weighing 300 g or more are adult fish with a body length of 30 cm or more.
Consideration:
It was found that the growth of yamame trout was promoted when the active stone 16 was ^{immersed in more than 70 kg per 1 m 3 of breeding water.} It was found that a larger amount of active stone 16 is required when culturing in cold water than when culturing in warm water.

An experiment was conducted in which it was confirmed whether or not the aquaculture facility 1 according to the present embodiment could cultivate fish and shellfish with an excessive individual density exceeding the standard aquaculture individual density, thereby confirming the effect of the active stone.
Experimental method: dipping the activity stone 16 of 50kg per 1 m ³ in breeding water in the pond K, the water temperature is such that the 24 to 27 ° C., containing ozone so that the ozone concentration becomes 0.001~0.002ppm Supplyed air. Pond and breeding water 1m ³ 500 animals per discharge the Croc to K.
^{Immerse 100 kg of active stone 16 per 1 m 3 in} pond L so that the water temperature is 14 to 17 ° C and supply ozone-containing air so that the ozone concentration is 0.001 to 0.002 ppm. did. Trout were released 100 animals per breeding water 1m ³ to the pond L.
Experimental result:
When landed 6 months later, 30% of the eels in Pond K grew to 200 g or more of eels, and 5% grew to 80 to 200 g of eels. However, 65% were in a crocodile state or a crocodile state. In the pond L, the average weight of the yamame trout was 80 g. In addition, less than 1% of individuals died during aquaculture for both crocodile and yamame trout.
Consideration:
If a sufficient amount of active stone is immersed in breeding water and ozone is supplied to a predetermined concentration, it is possible to cultivate to some extent even if the aquaculture is carried out at an excessive individual density exceeding the standard aquaculture individual density. It turned out that there was. It can be said that it is the effect of activated stone and ozone. However, it was also found that aquaculture with excessive population density reduces the proportion of large-growing individuals.

The aquaculture facility 1 according to the present embodiment can be modified in various ways. For example, although it was explained that the active stone 16 is immersed in the pond 2, a dedicated pond that does not contain seafood or a large filtration device is provided separately from the pond 2, and the activated stone 16 is immersed in the pond 2, that is, immersed. You may try to do it. In this way, since the active stone 16 is not put in the pond 2 for cultivating seafood, the maintenance of the pond 2 becomes easy. Although the activation stone 1 has been described as being put in a net body, a plurality of such net bodies may be put together in a relatively strong metal basket. In this way, the active stone 1 can be easily carried in / out by suspending the basket with a heavy machine or the like. It is also possible to omit the filtration device 3. In other words, like a pond in a conventional eel farm, feces and residual food may be manually pumped, and a predetermined amount of breeding water may be supplied from the outside every day to drain the predetermined amount. Air containing ozone can also be deformed. It was explained that the air containing ozone is made into bubbles from the micropores made in the nozzle portion 20 and ejected into the breeding water, but the ultrafine bubbles called microbubbles are generated by a dedicated bubble generator. It may be supplied to the breeding water.

1 Aquaculture equipment 2 Pond 3 Filtration device 5 Pressure vessel 6 Filtration material 11 Pump 16 Active stone 17 Aeration device 20 Nozzle part

Claims (4)

An aquaculture method for cultivating eels, chars, or yamame trout in stored breeding water.
A predetermined amount of crushed bakuhan stone is immersed in the breeding water, and air containing ozone is supplied to the breeding water.
In the case of eels, ^{soak 35 kg or more per 1 m 3} of breeding water, and in the case of char or yamame trout, soak 70 kg or more per ^{1 m 3 of breeding water.}
A method for culturing eels, chars, or yamame trout, wherein the supply of air containing ozone is adjusted so that the ozone concentration of the breeding water is 0.001 to 0.005 ppm. In farming method according to claim 1, air containing the ozone supplied from below the elvan, the elvan is characterized in that to be exposed to the bubbles of air containing the ozone eel , Iwana, or yamame trout farming method. An eel, char, or yamame trout farming facility that stores breeding water.
In the aquarium or pond of the aquaculture facility, a predetermined amount of crushed bakuhan stone is immersed in the breeding water, and air containing ozone is supplied to the breeding water.
The barley stone, is immersed or 35kg per breeding water 1 m ³ in the case of eels, when the char or trout is immersed 70kg or more per breeding water 1 m ^3,
An eel, char, or yamame trout farming facility, wherein the supply of ozone-containing air is adjusted so that the ozone concentration of the breeding water is 0.001 to 0.005 ppm. In farming equipment according to claim 3, the air containing the ozone eel, characterized in that it is supplied by air bubbles from below the elvan, char or aquaculture facility Yamame.

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