JPH08107732A - Culture of fishes and shellfishes - Google Patents

Abstract

PURPOSE: To provide a method for culturing fishes and shellfishes having a reproduction rate of about 6 times compared with a case in which surface water is used when phytoplankton is cultured using an artificial deep water, and thus enabling culture of fishes and shellfishes in good efficiency. CONSTITUTION: A sea area for culturing fishes and shellfishes is relatively widely set and enclosed by a barrier and a seedling floor for phytoplankton is provided in the interior and the seedling floor is cultured by artificial deep water to raise and proliferate the phytoplankton. The culturing sea area is stocked with a part of the proliferated phytoplankton to raise and proliferate the shellfishes and also fries and young fishes. The remainder is introduced into a seedling floor 22 for animal plankton and a cultured sea area is stocked with the proliferated animal plankton to raise and proliferate fishes. Thereby, construction of extremely natural marifarm not bringing excess eutrophication of sea water is made possible.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for cultivating fish and shellfish, and more particularly to a method for cultivating fish and shellfish based on the purpose of growing phytoplankton using artificial deep water.

[0002]

2. Description of the Related Art Conventionally, aquaculture of seafood, especially edible fish, has been
A relatively narrow sea area is surrounded by a fishing net etc. as a barrier, and fry or juveniles separately cultivated up to a prescribed size are released into the barrier to give excess food, antibiotics and, in some cases, growth hormone agents, etc. Is to be administered to an adult or a state close to it within a relatively short period of time and commercialized.

[0003]

However, since fish do not have the habit of preying on the submerged bait, an overdose of the bait is inevitably generated, which is near the aquaculture area. It causes eutrophication and contaminates seawater, and the administration of antibiotics and hormones causes environmental pollution, and since humans eventually ingest such fish, there is a concern that it may affect the human body. Therefore, it is an object of the present invention to cultivate seafood within a closed sea area and in an extremely close to natural condition, thus eliminating the risk of environmental destruction in prior art methods.

[0004]

[Means for solving problems and achieving objectives] Good fishing grounds are found in areas where so-called "deep water" is upwelling, and the catches in these areas correspond to about 50% of the total catch. It is known that the definition of `` deep water '' is not clear, but it refers to seawater at a depth where the mineralization and decomposition processes are superior to the synthesis of organic substances by photosynthesis, that is, the depth beyond the so-called compensation depth. It shall be). Deep water is stable with low fluctuations in water quality, has a low water temperature (about 5 ° C), and is rich in inorganic salts, especially phosphates, nitrates and silicates, necessary for the growth of photosynthetic algae (phytoplankton). And their composition ratio is stable, there are few parasites and microorganisms that parasitize fish and shellfish, and there is little influence of heavy metals and artificial pollutants,
Therefore, it has advantageous properties such as high cleanliness. Therefore, when seafood is cultivated using natural deep water, it has been experimentally found that its growth rate is remarkably high and its taste is remarkably excellent. Although it has already been proved, it is rare that the deep water rises to the sea surface, and the area of the deep water near the sea surface is about 0.1% of the total ocean area. Until recently, there have been no attempts to positively utilize deep water for aquaculture of seafood in terms of the cost required for its collection and transportation.

The present invention pays attention to the above-mentioned characteristics of deep water, and artificially prepares deep sea water or seawater having characteristics superior to this by utilizing surface water, that is, seawater having a depth less than the compensation depth. , Thereby growing and propagating phytoplankton in the nursery, releasing the proliferated phytoplankton to the seawater culture area surrounded by the barrier, and growing zooplankton in the separate nursery with the phytoplankton. It is proliferated, and the proliferated zooplankton is released into the seafood culture area of the seafood, and is cultured by an extremely natural food chain (phytoplankton → zooplankton / juvenile / larva → small seafood → large seafood). is there.

The artificial deep water used in the method of the present invention can be obtained by collecting surface water, purifying it, analyzing the components, and adjusting the components based on the following component table. The purification treatment can be performed by first permeating the sand layer and then filtering, and then sterilizing with sodium hypochlorite or filtering using a sterilization filter. However, if it is collected relatively offshore and confirmed to be clean, the purification treatment can be omitted.

[0007]

[Table 1]

Phosphorus, nitric acid and nitrogen components in the above components are present in the upwelling deep layer water, but are so small that they are not present in the surface layer water. A trace amount of iron or copper can be added, for example, in the form of ferric sulfate [Fe ₂ (SO ₄ ) ₃ ] or cupric sulfate (CuSO ₄ / 5H ₂ O) (compounding amount: per 1 kg of seawater). about
0.00001-0.000015g).

The phytoplankton to be grown using the artificial deep water as described above is a diatom Chaetocer.
os ceraatosporm , Skeletonema costatum and Nannochr
olopsis oculata , the green alga Hallimeda Symlans and Hallimeda gorreauii , the red alga Launencia pait
ei and Chondria tenuissima , Phormid , a cyanobacteria
ium persicium , dinoflagellate P. trocoidem and E
xuviella cassubica , Stypopodium zonal , a brown alga
Examples thereof include e and Diprophus guinensis , haptoalgae , and Plasmophyta . Zooplankton to be grown by using such phytoplankton include Crustacea copepoda and Crustacea euphaus which are crustaceans.
iacea , a protozoan Protozoa sarcodia radiolari
a, it is a coelenterate Coelenterata hydromedusae, Coelen
terata ctenophora , Coelenterata scyphomedusae , Cha
Examples include etognatha sagitta and Chaetognatha eukrohnia .

[0010]

[Examples, etc.] Test example (phytoplankton breeding / propagation experiment) As a result of surveying each place for artificially uncontaminated seawater, Hachijojima was selected and a phytoplankton breeding / propagation test was conducted. That is, surface water was collected (collection depth: 40
m), using this surface water, or using this surface water and using the artificial deep water prepared in the above-described manner, a static culture experiment of Skeletonema costatum of the phytoplankton diatom Skeletonema costatum was performed. In the case of artificial deep water, the degree of proliferation was found to be more than 6 times that of the surface water itself. Therefore, if artificial deep water is used, artificial multiplication of phytoplankton is possible, and if this multiplied phytoplankton is released into the sea, shellfish (clams, clams, blue mussels, etc.) and fry / larvae can be cultured. Further, if this phytoplankton is given to zooplankton, it becomes possible to proliferate it. Therefore, it is a matter of course that it is possible to cultivate various kinds of fish, squid, etc. by releasing this proliferated zooplankton.

Conceptual Example (Construction of Marine Ranch with Leisure Equipment) The present invention finally aims to construct an ocean ranch with leisure equipment. Therefore, this will be described with reference to the drawings. Figure 1 is a bird's-eye view of ocean ranch 10. As shown in Figures 2 and 3, floating bodies (buoys) 121
A barrier ring 12 composed of a synthetic resin film and a net 123 having micropores that reach the seabed and are fixed to each other constitutes one closed sea area for fish culture. The appropriate diameter of this barrier ring is about 5km. Aquacastle at the center of the barrier ring
(Sea Castle) 14 are placed. This Aqua Castle 14
Is a continental shelf city that the applicant previously proposed (Japanese Patent Application Laid-Open No. 6-2210
3), but if placed in a submerged state on a sandy bottom of the sea floor, the sand may be shaved by the ocean floor current, resulting in an unstable state.For example, as shown in Figure 4 to Figure 6, Tension that is locked on the seabed
It is preferable to fix it in a stable state with a wire. Aquacastle 14 is a landing place for transport ships and tourist ships, a mooring area for work vessels, a raw material tank for preparing artificial deep water, its preparation section and storage tank, and a control tower equipped with radar and communication antennas, etc. , A residential station, a helicopter departure / arrival port, a main station 141 with a pool,
An underwater city 143 connected to the main station 141 via a pipeline 142 for elevators of several tens of meters,
It has a corridor aquarium 145 connected to the underwater city 143 by a ribbed conduit 144, and a floating body 146 that keeps these structures in a floating state. The main station 141 is equipped with a landing site for carriers and helicopter landing ports because this marine ranch is set offshore from the land, and the size of the subsea city 143 is 30 m high. , A diameter of about 80 m is assumed, and a ribbed pipeline 144
It is appropriate that the diameter of the pipes that make up the corridor-type aquarium 145 is about 6 m.
It is preferable that the outer diameter of the pipe line 142 connecting with 143 is about 20 m in consideration of strength and the like. The floating body 146, which keeps the structures such as the main station 141 and the underwater city 143 in a floating state, is fairly large, and is therefore not only an object that merely provides buoyancy, but also various functions, such as for scuba divers. It may have a function of a base, a warehouse, and the like.

As is apparent from FIG. 1, the aquacastle 14 is also surrounded by a ring-shaped structure 16,
As shown in Fig. 7, this ring-shaped structure 16 has dividing parts 161, 161 for allowing ships to enter and exit, and is connected to floating bodies 146, 146 by fixing pipes 18, 18 and a connecting bridge 20. , 20 connected to main station 141. The width of the above-mentioned ring-shaped structure is about 30 m, and the diameter is preferably about 300 m, which is the tip and the rear of the hollow watertight pipe 163 made of steel, fiber reinforced plastics (FRP) or synthetic rubber shown in Fig. 8. Units have engaging parts 163a, 163b with eye holes at the ends.
(The total length is 5 m, the outer diameter of the pipe is 35 cm), use the engaging part as shown in Fig. 9, and connect with bolts and nuts.
Assembled in a grid as shown in. As shown in Figure 10, some of the grids have reinforcement braces.
(Glasses) 165, 165 are attached, and the lattice-shaped portions to which the braces are attached are arranged in a zigzag shape as shown. A nursery for growing and multiplying phytoplankton with artificial deep water in the remaining grid 16
7 and 167 are set, but if the nursery is set on all the remaining lattice-like parts, the landscape will be poor when looking at Aquacastle 14 from a distance. Therefore, three-dimensional nets 169, 169 were attached to some of the grid-like parts, and trees that grow even in the presence of seawater were grown hydroponically to form mangroves. It is preferable to bring the image of the castle surrounded by and.

In the sea area between the barrier ring 12 and the ring-shaped structure 16 described above, a large number of zooplankton nursery beds 22 and 22 for breeding and growing are shown in FIGS. 1 and 2. Is located in. These zooplankton nurseries have a diameter of about 100 m and a depth of about 20 m, and can be made of synthetic resin such as vinyl chloride, and the seawater contained inside does not necessarily have to be artificial deep water.
Figure 1 shows the sea area where zooplankton nurseries are located.
As shown in Fig. 2 and Fig. 2, the number of solar-introducers 24, 24 with optical fibers set in the concentrator, solar-powered upwelling devices 26, and wind-powered upwelling devices 28 are appropriately arranged to enable deep seawater Bring updrafts to.

When operating the marine ranch constructed as described above, the main station of Aquacastle 14
The artificial deep water prepared in 141 is transported to the ring-shaped structure 16 by the work boat and injected into the phytoplankton breeding / propagation nursery beds 167 and 167 by the pump, and the collected phytoplankton is introduced into the nursery beds. Then, the cells are statically cultured. If the phytoplankton grows by culturing, the work boat will tow the zooplankton breeding / propagation seedbed 22 to the ring-shaped structure 16, so to speak, by a work boat, and the phytoplankton in the seedbed 167 will be artificially pumped. It is transferred to the zooplankton nursery with the deep water, and this is repeated to introduce a specified amount of phytoplankton into the zooplankton nursery, and this work is also performed for the other zooplankton nursery beds 22 and 22. The introduced zooplankton nursery 22 is towed to a predetermined position by a work boat. Part of the propagated phytoplankton is released on the spot, or part of it is transported by work boats and released at various places in the marine ranch area to be used as food for shellfish, fry and juveniles. In addition, the zooplankton that has sufficiently propagated in the zooplankton nursery are released as food for fish to be cultivated.

[0015]

According to the method of the present invention, phytoplankton is cultivated using artificial deep water having a much higher concentration of nitrates, phosphates and silicates when compared with surface water, so that the growth and The growth rate is extremely high, and this phytoplankton is released to the aquaculture area, so it is expected that the growth rate of shellfish, fry and juveniles will be improved, and the cultured phytoplankton will also be introduced to the zooplankton nursery, so It is expected that the growth and multiplication rate will be improved, and that the zooplankton will be released into the cultured sea area, so that early growth of cultured fish is expected. If a marine ranch is formed by using the method of the present invention and a natural aquarium is provided on it, it becomes a suitable place for observing marine life.

[Brief description of drawings]

FIG. 1 is a bird's-eye view showing a panoramic view of an ocean ranch using a method for aquaculture according to the present invention.

FIG. 2 is a side view of the marine ranch shown in FIG.

FIG. 3 is a perspective view showing a part of the barrier ring forming the outer shell of the marine farm shown in FIGS. 1 and 2.

FIG. 4 is a perspective view of an aquacastle provided in an ocean ranch.

FIG. 5 is a side view of the aquacastle shown in FIG.

FIG. 6 is a perspective view showing the lower structure of the aquacastle shown in FIGS. 4 and 5 in some detail.

FIG. 7 is a plan view schematically showing the relationship between an aqua castle and a ring-shaped structure surrounding it.

8 is a plan view of a hollow watertight pipe which is a constituent unit of the ring-shaped structure shown in FIG.

9 is a plan view showing an attachment mode of the hollow watertight pipe shown in FIG. 8. FIG.

FIG. 10 is a plan view showing a part of a ring-shaped structure assembled by using the hollow watertight pipe shown in FIG.

[Explanation of symbols]

10: Marine farm 12: Barrier ring 14: Aquacastle 141; Main station 143; Underwater city 145; Corridor aquarium 16: Ring-shaped structure 163; Hollow watertight pipe (constituent unit of ring-shaped structure 16) 167; Plant Plankton nursery 20: Connecting bridge 22: Zooplankton nursery 24: Fiber optic solar introduction device 26: Solar cell upwelling device 28: Wind power upwelling device

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hiromi Tanaka 1-7-1 Kyobashi, Chuo-ku, Tokyo Toda Construction Co., Ltd. 2-304

Claims (3)

[Claims] 1. A seafood culture sea area is set relatively wide, surrounded by a barrier, and a phytoplankton seedbed containing artificial deep water is placed therein to propagate the plankton, and a separate zooplankton seedbed. Is also disposed, and the phytoplankton that has proliferated is transferred to the nursery to proliferate zooplankton, and the proliferated plants and zooplankton are discharged into the sea area surrounded by the barrier. The method of aquaculture of seafood. 2. A large, ring-shaped float structure is arranged in the center of the barrier, and a large number of phytoplankton-growing nursery beds are arranged on this float structure, and small and plural float beds are arranged around the float structure. The zooplankton breeding nursery of claim 1 is arranged, and a plurality of solar light concentrators using optical fibers are arranged.
The method for aquaculture of seafood according to 1. 3. Chaet , whose phytoplankton is a diatom
oceros ceraatosporm , Skeletonema costatum and Nann
ochrolopsis oculata , the green alga Hallimeda Symlan
s and Hallimeda gorreauii , the red alga Launencia
paitei and Chondoria tenuissima , the cyanobacterium Pho
rmidium persicium , dinoflagellate P. trocoidem and Exuviella cassubica , brown alga Stypopodium z
atale and Diprophus guinensis , at least one species selected from haptophytes and plaques algae,
On the other hand, zooplankton is a crustacean Crustacea copep
oda and Crustacea euphausiacea , a protozoan Pr
otozoa sarcodia radiolaria , a coelent coelent
erata hydromedusae , Coelenterata ctenophora , Coelen
terata scyphomedusae , Chaetognatha sagitta and Ch
The method for cultivating seafood according to claim 1 or 2, wherein the method is at least one kind selected from aetognatha eukrohnia .