JPH07213190A - Device for culturing marine organism - Google Patents

Abstract

PURPOSE:To stimulate the growth of fishes, etc., thereby increase the quantity of fishing in the whole area of a sea region, and reduce the cost of a feed by constructing a healthy food chain system for marine organisms. CONSTITUTION:The device for culturing marine organisms is provided with an underwater floating tank 2 moored in sea water W with anchor ropes 12, etc., and capable of storing a feed liquid S therein, and with a feed-releasing function member 3 capable of releasing the feed liquid S stored in the underwater floating tank 2 with proper portions into the sea water W.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a marine organism culture apparatus for constructing a healthy food chain system in marine organisms.

[0002]

2. Description of the Related Art Conventionally, a feeding and aquaculture system is known as a technique for aquaculture of fish in the ocean. In order to produce high value-added fish, this type of aquaculture method releases specific fish to the submarine or cages that have been sectioned and feeds them with aquaculture. ), Protozoa, natural foods such as Artenia and tigliopas, and artificial foods formed into granules or pellets based on fish and krill.

Therefore, in this type of aquaculture system, the cost of the feed given to the cultured fish occupies a considerable proportion of the production cost, and there are problems such as frequent occurrence of diseases due to overweight of the cultured fish and self-pollution due to residual food. In particular, illnesses of fish living in the ocean are extremely rare, but in the case of cultured fish, viral diseases, bacterial diseases, and mold diseases occur, and the use of drugs is also indispensable.

By the way, there are five stages of the food chain system in marine organisms, and the food chain becomes a food chain in the order of nutrients → phytoplankton → zooplankton → small, medium, and large fish schools. That is, 10 kg / fish eat 10 ² kg of small fish, and this 10 ² kg small fish group is smaller than 10 ³ small fish group.
eating kg, with eat small fish is smaller small fish 10 ⁴ kg of 10 ³ kg, small fish of 10 ⁴ kg eat zooplankton of 10 ⁵ kg, the 10 ⁵
kg of zooplankton eats 10 ⁶ kg of phytoplankton.

As described above, the conventional feeding and aquaculture system has not only problems such as increase in production cost and occurrence of diseases, but also a very serious problem that a healthy food chain cannot be maintained.

[0006] The present invention has solved the problems existing in such prior art, by promoting the growth of fish by constructing a healthy food chain system in marine organisms, thereby catching fish in the entire sea area. It is an object of the present invention to provide a marine organism culture device capable of increasing the feed cost and reducing the feed cost.

[0007]

A marine organism culture apparatus 1 according to the present invention comprises an underwater floating tank 2 moored in water, for example, seawater W, by an anchor, etc., and capable of storing a feed liquid S therein. Feed liquid S stored in the underwater floating tank 2
Is provided with a discharge function part 3 capable of discharging a proper amount into the seawater W.

In this case, it is desirable to use a culture solution for marine microorganisms as the feed solution S. Further, the underwater floating tank 2 is moored vertically so that it can be formed of a film material. Furthermore, marine organism culture device 1
To replenish the inside of the underwater floating tank 2 with the feed liquid S, for example, a replenishment function part including a replenishment pipe 6 which is connected to the underwater floating tank 2 at one end and is supported by a buoy 5 floating at the other end on the water surface 4 and a stirring function unit 7 that stirs the feed liquid S stored inside the submersible floating tank 2 can be configured. Wave power pumps 8 and 9 can be used for the discharge function unit 3 and the stirring function unit 7.

[0009]

According to the marine organism culturing apparatus 1 of the present invention, the underwater floating tank 2 is moored by an anchor or the like in a state where it is submerged in seawater (water) W to an arbitrary depth. On the other hand, a feed solution S such as a culture solution for marine microorganisms is stored inside the submersible floating tank 2, and the stored feed solution S is released into the seawater W through the release function part 3.
In this case, the feed liquid S is released by an appropriate amount by the action of the wave pump 8. When the amount of the feed liquid S inside the submersible floating tank 2 is low, the feed liquid S is replenished into the submerged floating tank 2 via the replenishment function unit 4.

Therefore, the released feed liquid S serves as a nutrient source for marine microorganisms to promote the cultivation of marine microorganisms, and further, the food chain system allows the growth of zooplankton, small, medium and large fish schools. Is promoted and the original healthy food chain system is built. Therefore, unlike the conventional feeding and aquaculture method in which the feed is administered to specific fish in the partitioned seawater W, there is a risk of overweight and illness due to overeating of fish due to the construction of a natural food chain system. Disappears.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, preferred embodiments according to the present invention will be described in detail with reference to the drawings.

First, the structure of the marine organism culture apparatus 1 according to the present invention will be described with reference to FIGS.

The marine organism culture apparatus 1 comprises an underwater floating tank 2 for submersion in seawater W. The underwater floating tank 2
Excellent in tensile strength, bending strength, fatigue resistance, impact resistance, etc.,
For example, it is formed into a spherical shape by a film material using carbon fiber, steel fiber, ultra high strength polyethylene fiber, boron fiber or the like.

The submersible floating tank 2 has a holding frame F.
The air tank 11 is attached to the inside of the holding frame F, and the air tank 11 is attached along the circumference of the holding frame F. Holding frame F
Is anchored in the seawater W by the anchor rope 12 ..., preferably at an arbitrary depth near the water surface (within a depth of 20 to 30 m). Numerals 13 are weights attached to the anchor ropes 12 ... Numeral 14 is an air conducting tube connected to the air tank 11 for supplying and discharging air, and its tip is supported by the buoy 5.

On the other hand, a discharge function section 3 is provided at the bottom of the underwater floating tank 2. The discharge function unit 3 includes a discharge pipe 15 extending downward from the bottom surface of the submersible floating tank 2 and a discharge box 16 provided at a lower end of the discharge pipe 15, and a plurality of discharge ports 17 are provided around the discharge box 16. Have ... The lower end of the pump pipe 18 is connected in the middle of the discharge pipe 15 and the wave pump 8 is connected to the upper end of the pump pipe 18. As shown in FIG. 2, the wave pump 8 is a diaphragm type in which the bellows type air chamber 19 expands and contracts due to the change in water pressure due to the change in the height of the wave We, or the float moves up and down near the sea surface due to the change in the height of the wave We. It is possible to use a piston method or the like that performs movement. Further, the valve body 20 is arranged above the connection position of the pump pipe 18 in the discharge pipe 15, and
The valve body 21 is arranged below the connection position.

On the other hand, a replenishment function section 4 is provided above the submersible floating tank 2. The replenishment function unit 4 includes a replenishment pipe 6, one end of which is connected to the upper portion of the submersible floating tank 2 and the other end of which is supported by a buoy 5 floating above the sea surface. Further, the submersible floating tank 2 is provided with a stirring function unit 7. The stirring function unit 7 is composed of a stirring unit main body 22 arranged inside the submersible floating tank 2 and a wave power pump 9 arranged in the seawater W to cause the stirring unit main body 22 to function.

The liquid feed S is stored in the submersible tank 2. Since the feed liquid S is aimed at the initial stage of the food chain system, it is a culture liquid type for marine microorganisms. Therefore, as the feed liquid S, for example, cake (feces) before incineration discharged from a human waste treatment plant that processes livestock manure or human excrement is composted, and the powder obtained after deodorization and detoxification is melted. Is available. Such a feed solution S contains a phosphoric acid content and is excellent in water solubility. In addition, as the feed liquid S, residues and waste liquid discharged during food processing, food processing by-products such as moromi waste liquid discharged during the brewing process of alcoholic beverages, and waste beet sugar liquid and fruit processing discharged from a sugar factory Agricultural product processing by-products such as residue and waste liquid can be used.

Next, the function of the marine organism culture apparatus 1 according to the present invention will be described with reference to FIGS.

First, the feed liquid S is stored inside the submerged floating tank 2. In this case, as shown in FIG. 3, the upper end of the supply pipe 6 supported by the buoy 5 is connected to the ship M, and the feed liquid S is supplied to the supply pipe 6 from the supply device mounted on the ship M.
As a result, the feed liquid S is supplied to the inside of the underwater floating tank 2 through the supply pipe 6. When the supply of the feed liquid S is completed, the upper end of the supply pipe 6 is closed and the buoy 5 is supported again. Note that, in FIG. 3, the underwater floating tank 2 indicated by a solid line
Shows the state after replenishment, and the underwater floating tank 2x in the phantom line shows the depressed state before replenishment.

On the other hand, the bait solution S is released from the inside of the underwater floating tank 2 into the seawater W from the releasing function section 3 in an appropriate amount. In this case, in the case of the diaphragm system shown in FIG. 2, if a high wave We pushes against the wave force pump 8, the water pressure against the wave force pump 8 increases, so that the air chamber 19 is compressed as shown by the solid line. On the other hand, after the wave We leaves, the water pressure decreases, so that the air chamber 19 expands and returns to the original state as shown by the phantom line. Therefore, when the air chamber 19 is compressed and expanded, the pump pipe 18 is in a suction state, the valve body 20 (phantom line) is opened, and the valve body 21 (phantom line) is closed. As a result, the feed liquid S inside the submersible floating tank 2 is discharged between the valve bodies 20 and 21 (see arrow H1).
On the other hand, when the air chamber 19 is expanded and compressed, the pump pipe 18
Is pressurized, the valve body 20 is closed, and the valve body 21 is opened. As a result, the feed liquid S between the valve bodies 20 and 21 is discharged from the outlet 1
7 ... is discharged into the seawater W (see arrow H2). In this way, the discharge operation is repeated corresponding to the wave and is automatically performed.

In the stirring function section 7, the stirring section main body 22 functions by the wave force pump 9 which operates on the same principle as the above wave force pump 8. That is, in response to the compression or extension operation of the wave pump 9, the feed liquid S is sucked in from the lower water inlets 22d ... Of the stirring unit main body 22 and discharged from the upper outlet 22u. Liquid S in
Is stirred.

The underwater floating tank 2 in the seawater W
The depth of can be arbitrarily set by adjusting the amount of air in the air tank 11. In this case, in order to settle the submersible floating tank 2, an air valve provided at the tip of the air conduit 14 is opened, and in order to float, air is sent from the ship M.
Therefore, if the air in the air tank 11 is discharged during a typhoon and lowered like the underwater floating tank 2y shown in phantom in FIG. 3, it is possible to dive to a depth (depth of about 50 m) that is not affected by waves. it can.

The embodiment has been described in detail above.
The present invention is not limited to such an embodiment.
For example, although the ocean is illustrated, it may be a lake or the like. In addition, the detailed configuration, shape, material, quantity, etc. can be arbitrarily changed without departing from the scope of the present invention.

[0024]

INDUSTRIAL APPLICABILITY As described above, the apparatus for cultivating marine organisms according to the present invention comprises an underwater floating tank moored in water by an anchor rope or the like and capable of storing a food solution therein, and a food solution stored in the underwater floating tank. Equipped with a release function unit that can release an appropriate amount into water, by building a healthy food chain system in marine life, it is possible to promote the growth of fish, thereby increasing the catch in the entire sea area and reducing the feed cost. There is a remarkable effect that can be achieved.

[Brief description of drawings]

FIG. 1 is a vertical sectional front view of a main part of a marine organism culture apparatus according to the present invention,

FIG. 2 is a vertical sectional front view of a release function part in the marine organism culture apparatus,

FIG. 3 is an overall configuration diagram of the marine organism culture device,

[Explanation of symbols]

 1 Marine organism culture device 2 Underwater floating tank 3 Release function part 4 Replenishment function part 5 Buoy 6 Supply pipe 7 Mixing function part 8 Wave power pump 9 Wave power pump S Feed liquid W Seawater

 ─────────────────────────────────────────────────── ─── Continuation of the front page (71) Applicant 592025904 Minoru Kamimori 1-3-3-33 Kiyoshu, Kashiwara City, Osaka Prefecture 505 (71) Applicant 592025915 Futoshi Kanuma 1-Miyazaki, Miyazaki-ku, Kawasaki City, Kanagawa Prefecture No. 4-40- 304 (71) Applicant 592116936 Kiyoshi Kaneshiro No. 264, Seisakusen, Urasoe City, Okinawa Prefecture (71) Applicant 592025926 Masahiro Kaneshiro 3-5-22, Yoriya Naha City, Okinawa Prefecture (71) Applicant 592025959 Tsunoda Toyohashi 2-21-9 Ihara, Koshigaya City, Saitama Prefecture (71) Applicant 592116947 Koji Hirara 4-chome, Jouma, Urasoe City, Okinawa Prefecture 4-103 (71) Applicant 592116958 Tomizo Tasato Character Plateau, Okinawa City, Okinawa Prefecture Address 1270 (71) Applicant 592023715 Toma Take 15 Tomigusuku-mura, Shimajiri-gun, Okinawa Prefecture, Ueda, 15 (72), 43, Ueda Toshiyuki Suzuki Toshiyuki Suzuki, Urasoe, Okinawa Prefecture 1 (72) Inventor, Utsunomiya Sentence, Satio Otomo, No. 206, Ohira 206, Urasoe City, Okinawa Pref., Sadao Otomo 893-1 Amaku, Naha City, Okinawa Pref. 301, Amaku Grand Heights 301 (72) Minoru Kamibara, 1-3-3, Kiyosu, Kashiwara, Osaka 505 Kashiwara 505 (72) Inventor Nizuma Kazuma No. 1-4-40-304 Miyazaki, Miyamae-ku, Kawasaki City, Kanagawa Prefecture (72) Inventor Kiyoshi Kaneshiro 264, Seisakusen, Urasoe City, Okinawa Prefecture (72) Masahiro Kaneshiro, Okinawa 3-3-5-231 Yorinomiya, Naha, Japan (72) Inventor Yutaka Tsunoda 2-21-9 Ihara, Koshigaya, Saitama (72) Inventor Koji Hirara 4-chome, Jouma, Urasoe, Okinawa 4-government dormitory 4- 103 (72) Inventor Yuzo Tasato 1270, Kogen, Okinawa City, Okinawa Prefecture (72) Inventor Tomu Take Ueda 43-15, Tomigusuku Village, Shimajiri District, Okinawa Prefecture

Claims (10)

[Claims] 1. A moored underwater by an anchor rope or the like,
A marine organism culturing apparatus comprising: an underwater floating tank capable of storing a bait liquid therein; and a release function unit capable of releasing an appropriate amount of the bait liquid stored in the underwater floating tank into water. 2. The marine organism culture apparatus according to claim 1, wherein the submerged floating tank is moored in seawater. 3. The marine organism culture apparatus according to claim 1, wherein the feed liquid is a culture liquid for marine microorganisms. 4. The marine organism culture apparatus according to claim 1, wherein the submerged floating tank is moored so as to be movable up and down. 5. The marine organism culture apparatus according to claim 1, wherein the submerged floating tank is formed of a membrane material. 6. The apparatus for cultivating marine organisms according to claim 1, wherein the discharge function unit uses a wave power pump. 7. The apparatus for cultivating marine organisms according to claim 1, further comprising a replenishment function section for replenishing the feed liquid into the submersible floating tank. 8. The apparatus for cultivating marine organisms according to claim 1, wherein the replenishment function part has a replenishment pipe having one end connected to the underwater floating tank and the other end supported by a buoy floating on the water surface. 9. The apparatus for cultivating marine organisms according to claim 1, further comprising a stirring function section for stirring the feed solution stored in the submersible tank. 10. The apparatus for cultivating marine organisms according to claim 1, wherein the stirring function section uses a wave power pump.