KR20190085386A - Farming equipment for artificial seeds of shellfish planktonic stage - Google Patents

Abstract

The present invention relates to an artificial seeding culture facility of a shellfish floating machine, which improves efficiency and productivity of a work. The artificial seeding culture facility of a shellfish floating machine of the present invention comprises: a hexahedral water tank unit; a plurality of larvae receiving units arranged in parallel in the water tank unit; a seawater supply pipe unit provided to correspond to a position of the larvae receiving units; and a seawater discharge pipe unit provided to discharge seawater.

Description

{FARMING EQUIPMENT FOR ARTIFICIAL SEEDS OF SHELLFISH PLANKTONIC STAGE}

The present invention relates to an artificial nursery culture facility for shellfishes, and more particularly, to a facility for easily culturing larvae of artificial nursery larvae, which is a period of floating in water among artificial nursery shellfishes.

In general, shellfish is a kind of molluscs having a calcareous shell, which includes a single-plate steel, a multi-plate steel, a bamboo steel, (亞 classes) and a few parts of the Fujia River, the Gugu River (足 足), the Biparang River (枚 貝)), and the Bazaru River (足 足 根).

Among them, the bivalve is called a bivalve, and its feet are shaped like an ax, which is also called a tribal river. These bodies are wrapped with symmetrical shells connected by ligaments, and without a radula, It is obtained by filtration of the food in the water with gill using a watering hole.

Among the bivalves, clams, cockles, eggshells, and birds are abundantly present in the coast of Korea. They are planktonic larval stages from non-adherent to vegetative stages, (Burrower) that grows into sediments such as mud.

Unlike cultivated species that can feed and nutrients in cages or indoor aquariums, the benthic bivalve bivalves collect natural sparrows in a tidal flat with high dependence on the natural environment, Therefore, the breeding aquaculture industry is maintained only after continuous reproduction in the natural habitat.

Recently, shellfish such as oysters, abalones, shellfishes, scallops, clams, lilies, and gourami have been cultivated in various ways. In the past, domestic seeds of seafood have been dependent on natural seeds. Recently, .

In other words, various techniques have been proposed to cultivate artificial seedlings in the aquatic tanks due to the lack of resources due to unstable supply of natural seedlings due to marine environmental pollution and indiscreet overfishing.

1 is a conceptual diagram showing an artificial nursery culture facility of a shellfish floating device according to the prior art.

As shown in FIG. 1, a conventional conventional technique has a square water tank with a rectangular parallelepiped inner surface, and the wall surface is formed of a cement material or the like.

In this water tank, the bubbles for surviving the larvae of the organisms are activated while the sea water is held. When the living water has a length of about 300 to 400 袖 m, it grows as a mid-breeding period spore and sinks to the bottom of the water tank , And the growing spore is separated and separated from the larvae of the organic organisms, and then transferred to other environments and raised.

However, in order to separate and harvest the spatula, which is an intermediate breeding period in the above-mentioned water tank, there is a problem that it is difficult to work because the operator has to directly enter the water tank in the state where the sea water is in the tank. In order to increase the working efficiency slightly, When separated and harvested, there is a problem that the larvae of the non-growing organisms that have not yet grown to spoil may die or be lost.

In addition, there is a problem in that when the spatula that has entered the middle breeding season from the state in which the excrement of larvae are continuously accumulated, sinks to the bottom, the feeding activity and the transformation operation are obstructed and the animal is often killed.

In particular, since the water tank is filled with seawater, the bubbles must always be operated for survival of the larvae, so that installation costs are increased and additional maintenance costs such as electricity charges are increased.

On the other hand, the bubbles used for the survival of the larvae produce bubbles in the seawater. These bubbles are commonly avoided by shellfish, and the bubbles often cause the larvae of the organism or the middle breeding season to die. There is a problem that occurs.

KR 10-0760272 B1 KR 10-1285112 B1 KR 10-1108643 B1 KR 20-0241833 Y1

DISCLOSURE OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a method for separating and harvesting larvae, The present invention provides an artificial nursery culture facility for shellfishes having a structure capable of separating and harvesting spatulas within a range that minimizes the damage to human bodies.

It is another object of the present invention to provide an artificial nursery culture facility for shellfishes having a structure for allowing excretion generated from larvae of organic organisms to be easily discharged to the outside without any special operation.

It is another object of the present invention to provide a shellfish artificial nursery culture facility having a structure that eliminates installation of bubbles to reduce installation cost and maintenance cost and minimizes larvae death due to foam generated from bubbles.

The problems to be solved by the present invention are not limited to the above-mentioned problems, and other problems to be solved by the present invention, which are not mentioned here, As will be appreciated by those skilled in the art.

The shellfish organic artificial nursery culture facility according to the present invention comprises a hexagonal water receiving part provided with a receiving space therein and a partition part dividing upper and lower spaces, A plurality of water receiving unit units provided in the water receiving unit in parallel with each other in the water receiving unit, and a channel which is spaced above the water receiving unit and connected to the water receiving unit and is capable of supplying seawater introduced thereinto, And a seawater discharge pipe portion provided with a supply pipe portion and a channel formed at a lower side of the water receiving portion to discharge the seawater.

The seawater culture system for shellfishes according to the present invention can remove only the larvae receiving unit and separate the fishes from the larvae that are grown in the medium growing unit, which is an intermediate breeding period, so that efficiency and productivity can be improved, , It is possible to separate and harvest the spatula within a range that minimizes the damage to the larvae of the non-organic organisms.

Since seawater flowing in the seawater supply unit continuously flows through the bottom mesh of the larva receiving unit, the seawater stored in the larva receiving unit forms a descending water stream, so that the larva excreta can be easily discharged to the outside without any special operation It is effective.

In addition, since the amount of dissolved oxygen in the seawater flowing into the water tank can be maintained by continuously flowing the seawater, the installation cost and the maintenance cost can be reduced by excluding the installation of the bubbles necessary for survival of the shellfish larvae have. By eliminating the installation of such bubbles, it is possible to minimize the loss of larvae due to the bubbles generated from the bubbles.

Figure 1 shows an example of an existing technique.
FIG. 2 is a perspective view of a shellfish organism artificial nursery culture facility according to the present invention.
FIG. 3 is a cross-sectional view of the artificial nursery culture facility for shellfish according to the present invention.
4 is a conceptual view of the flow of seawater in the shellfish organism artificial nursery culture facility according to the present invention.
FIG. 5 is a perspective view of a larvae receiving unit of the artificial nourishment facility for shellfishes according to the present invention.
6 is a cross-sectional view of a larvae receiving unit of a shellfish organism artificial nursery culture facility according to the present invention.

The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

The artificial nursery culture facility for shellfish according to the present invention is installed in an indoor space on the land adjacent to the sea and is supplied with seawater from the sea and is used for artificial nursery culture for cultivating larvae of the shellfish (about 400 μm or less in length) As shown in Figs. 2 to 3, a water receiving unit 1 having a receiving space therein and having a partition wall 12 dividing the upper and lower spaces is provided, (2) having a mesh part (21) provided in a lower part of the water receiving part (1) and provided with a mesh part (21) (3) having a channel for supplying seawater corresponding to the position of the larva receiving unit (2), and a channel is formed at a lower side of the receiving unit (1) to discharge the seawater Seawater available And a discharge tube 5.

First, the water receiving unit 1 is provided in a hexahedron shape having a receiving space provided therein and a partition wall capable of dividing the upper and lower spaces.

The water receiving portion 1 is formed to be large enough to accommodate the following larval receiving unit portion 2, and is capable of receiving seawater flowing therein.

In addition, a plurality of the water receiving units 1 may be provided and spaced apart from each other.

The water receiving portion 1 is provided so that the upper portion thereof can be opened to confirm the inside of the water receiving portion 1 and the sea water supply pipe portion 3 described below is provided at the upper portion of the water receiving portion 1 to receive seawater falling downward.

It is preferable that the upper portion of the water receiving portion 1 is provided so as to be selectively openable so as to be able to close the upper portion in a situation where the upper portion is required to be closed as in the case of rainfall.

The partition wall portion 12 provided in the water receiving portion 1 is provided in the middle portion of the water receiving portion 1 in a plate shape parallel to the paper surface so as to divide the upper and lower spaces of the water receiving portion 1 .

The partition wall portion 12 may be configured to selectively control the flow of seawater flowing into the water receiving portion 1.

Specifically, the partition wall portion 12 is provided in the middle portion of the water receiving portion 1 and is formed in close contact with the following larval receiving unit portion 2, so that the seawater inside the water receiving portion 1 is upward and downward And a plurality of through holes that can be selectively opened and closed are provided on the plate of the partition portion 12 so as to allow the flow of the seawater.

This is a configuration for controlling the flow amount of the seawater in the water receiving section 1 and the height of the sea surface in the following larval receiving unit section 2.

The partition wall portion 12 is formed in such a form that the following larval receiving unit portion 2 can be placed in the middle portion of the receiving portion 1 .

In addition, the water receiving portion 1 is further provided with an inclined portion 11.

The inclined portion 11 is formed as an inclined surface that forms a bottom surface of the water receiving portion 1 and is lowered toward the seawater discharge pipe portion 5 described below.

The inclined portion 11 is configured to easily guide the foreign matter and excrement to be formed on the bottom of the water receiving portion 1 to the seawater discharge pipe portion 5 described below, The seawater can also flow more easily toward the following seawater discharge pipe part 5, and the seawater can also flow more easily toward the following seawater discharge pipe part 5.

Next, a plurality of the larva receiving unit 2 are provided in the water receiving unit 1 in such a manner that the upper part is opened and the mesh part 21 is provided below.

The larva receiving unit unit 2 is a place that accommodates and nourishes the larvae A and is located inside the receiving unit 1 and is open at the upper side and opened at the lower side, A portion 21 is formed.

The larvae (A) are naturally grown in the form of floating in the larva receiving unit (2) as larvae of an organism.

At this time, it is preferable that the mesh part 21 is provided in such a size that the larvae A are not separated downward.

In addition, the mesh unit 21 is provided in a selectively replaceable form so as to be able to be replaced according to the size of the larva A. [

Specifically, it is preferable that the mesh portion 21 is formed with the largest mesh size within a size range in which the larvae A are not separated downward.

 Further, the larva receiving unit 2 further includes a seawater receiving unit 23.

In a preferred embodiment, the larva receiving unit 2 includes a first coupling part 22 provided in a protruding or groove shape along a lower outer circumferential surface so that coupling with the seawater receiving unit 23 can be easily performed, It is preferable to further provide the above.

The seawater receiving unit 23 is a structure for further increasing the fluidity of seawater flowing from above to below the larval receiving unit 2. [

Seawater is introduced from the upper part of the larva receiving unit 2 and the seawater discharged from the inside of the receiving unit 1 is totally downwardly discharged by the following seawater discharge pipe part 5 formed below the water receiving part 1 At this time, the fluidity of the screw-like fluidity is given to the lower part of the larva receiving unit unit 2, and the fluidity of the seawater whose flowability may be lowered by the mesh unit 21 can be increased.

Specifically, the seawater receiving unit 23 is formed in a tube shape that surrounds the lower end of the larva receiving unit 2, and is selectively provided in a lower portion of the larva receiving unit 2.

5 and 6, the seawater receiving unit 23 includes a second fastening portion 231, a current generating portion 232, and a seawater receiving portion 233, do.

First, the second fastening part 231 is provided in the form of a projection or a groove along the inner surface of the upper side of the seawater receiving unit 23 so as to be fastened to the first fastening part 22.

The second fastening part 231 may be formed in any form as long as it can be coupled with the first fastening part 22 in correspondence with each other.

Next, the current generating unit 232 is provided with a screw-shaped helix along the first half of the inner circumferential surface of the seawater receiving unit 23 so as to allow the inflowing seawater to flow spirally.

Accordingly, when the seawater flowing downward from above flows into the lower part of the seawater receiving unit 23, a constant flow in the form of a screw is generated through the spiral of the current generating part 232, The mesh portion 21 can be more easily passed through.

Next, the seawater receiving portion 233 is provided in the form of a plurality of through holes radially formed along the lower outer circumferential surface of the seawater receiving unit 23.

Specifically, the seawater storage unit 233 is provided with a plurality of through holes radially extending along the outer circumferential surface of the lower side of the seawater storage unit 23, and a through hole having a shape in which the upper part is somewhat narrowed, .

The seawater receiving portion 233 is configured to allow the seawater flowing downward from above to flow more easily into the lower portion of the seawater receiving unit 23. So that the outflow of the seawater is maximized and the upward flow of the seawater is prevented from spreading in all directions so that the overall flow of the seawater is easily generated in the downward direction within the water receiving section 1 .

More specifically, the seawater receiving portion 233 is formed with a through-hole, and the shape of the through-hole is configured such that the lower portion thereof is relatively wide and flows downwardly of the seawater receiving unit portion 23 Seawater can be effectively discharged and flowed.

The upward flow of the sea water can be suppressed in the lower part of the mesh part 21, so that the outflow of seawater to the outside can be suppressed due to the seawater receiving part 233 having a through hole shape that becomes relatively narrower toward the upper part .

Accordingly, the seawater can flow effectively toward the mesh portion 21, and a descending current can be formed in the larva receiving unit 2, thereby effectively reducing the foreign matter in the larva receiving unit 2 have.

 Further, the larva receiving unit (2) further includes a direct branch portion (24).

The direct branch portion 24 is provided on the upper part of the larva receiving unit 2 as a plurality of layers in the form of a mesh net.

4 and 6, when the seawater falling down from the upper part of the larva receiving unit 2 is directly introduced into the larva receiving unit 2, , And a foam is formed to prevent an environment favorable for the growth of the larvae (A) from being formed.

The seawater is distributed downward toward the larva receiving unit unit 2 and the foam is suppressed when the larva receiving unit unit 2 is poured into the larva receiving unit unit 2. [ .

Next, the seawater supply pipe section 3 is provided at a position spaced apart from the upper part of the water receiving section 1 and is provided so as to correspond to the position of the larvae receiving unit section 2 to supply seawater.

Specifically, the seawater supply pipe section 3 is provided with a channel formed to be spaced apart from the upper part of the water receiving section 1, and the seawater can be dropped downward at a position corresponding to the larval receiving unit section 2 An opening 31 is formed.

Next, in the seawater discharge pipe section (5), a channel is formed at a lower side of one side of the water receiving section (1) to discharge the seawater.

The seawater discharge pipe section (5) is a pipe through which seawater introduced into the water receiving section (1) is discharged.

At this time, since the seawater discharge pipe portion 5 is provided at a lower side of the water receiving portion 1, the flow of seawater formed in the water receiving portion 1 can be guided downward as a whole.

In addition, because the seawater is discharged through the seawater discharge pipe 5, foreign matter and larval excretion sinking downward can be easily discharged through the seawater discharge pipe 5.

As described above, it is to be understood that the technical structure of the present invention can be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention.

Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

A: Larvae
1:
11:
12:
2: Larch receiving unit
21: mesh portion
22: first fastening portion
23: Sea water receiving unit section
231: second fastening part 11
232: Current generating unit
233: Seawater reservoir
24: Office branch office
3: Sea water supply pipe
31:
5: Seawater discharge pipe

Claims (5)

In an artificial nursery culture facility installed in an indoor space on the land adjacent to the sea and supplying seawater from the sea and cultivating larvae of the shellfish (about 400 μm or less in length)
A receiving portion having a receiving space therein, and a partition wall portion dividing the upper and lower spaces;
A larva receiving unit unit including a plurality of water receiving unit units arranged inside the water receiving unit in such a manner that an upper part thereof is opened and a mesh part is provided below the water receiving unit unit;
A seawater supply pipe portion provided above the water receiving portion and provided with a channel capable of supplying seawater connected from outside and corresponding to a position of the larva receiving unit;
And a seawater discharge pipe portion formed at a lower side of the water receiving portion to discharge the seawater. The method according to claim 1,
Wherein a plurality of mesh nets are formed on the upper part of the larva receiving unit to further prevent direct seawater falling vertically from the upper part into the larva receiving unit. Artificial nursery aquaculture facilities. The method according to claim 1,
Wherein the larva receiving unit unit comprises:
And a seawater receiving unit unit provided in the lower part of the seawater receiving unit unit to selectively increase the amount of seawater flowing upward through the mesh part of the larva receiving unit unit by imparting a screw-shaped fluidity to the seawater incoming from the lower part,
And a first fastening part provided on the lower outer circumferential surface so as to be engaged with the seawater receiving unit part. The method of claim 3,
Wherein the seawater receiving unit comprises:
A second fastening part provided on the inner circumferential surface of the upper side in a protrusion or a groove shape so that the fastening part can be fastened to the first fastening part; And
A current generating part provided with a screw-shaped helix along the inner circumferential surface so as to flow seawater flowing in a spiral manner;
And a seawater receiving portion provided in the form of a plurality of through holes radially formed along the lower outer circumferential surface. The method according to claim 1,
Wherein the larva receiving unit unit comprises:
And an impurity generated from the larva is floated upward by seawater flowing upward from below through the mesh portion.

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