KR101043007B1 - Shellfish farming system - Google Patents

Abstract

Shellfish growing system according to the present invention is a seawater passage connected to the coast so that seawater can be supplied; A reservoir for storing sea water introduced through the sea channel; A shellfish growing module separated through the reservoir and the separating wall, wherein the shellfish is grown, and the shellfish growing module includes a tank in which shellfish is grown; A tank installation unit in which a plurality of tanks are arranged; A seawater supply unit which is formed to be inclined so that seawater may flow by a height difference, and communicates with the dividing wall to supply seawater to the water tank installation unit; A seawater recovery unit configured to be inclined so that the seawater passing through the water tank is moved by a height difference; A recycling unit pumping the seawater recovered by the seawater recovery unit through a pump and supplying the seawater back to the water storage tank; Since it includes a drain for discharging the seawater recovered through the seawater recovery unit to the outside, by forming a seawater path on the ground and receiving the seawater, the seawater can be supplied more smoothly, which can occur during the shellfish growth process. There is an effect that can prevent a large number of shellfish and grow a large number of shellfish without the power to bring the seawater to the ground because seawater is supplied from the sea channel formed on the ground.

Description

Shellfish farming system

The present invention relates to a shellfish breeding system, and more particularly, to form a seawater channel so that seawater flows into the land, and by arranging a shellfish breeding module for breeding shellfish in the seawater channel, shellfish breeding is simple and freedom of seawater. It relates to a shellfish breeding system that implements the circulation.

FIG. 1 shows a continuous drop-type proton 100 according to the prior art, and as shown in FIG. 1, the conventional continuous drop-form proton 100 maintains a plurality of rich children 101 at regular intervals, and thus, the parent string 104. The anchor 105 of the anchor line 103 connected to both ends of the mother line 104 is inserted into the seabed and fixed to the sea line, and the hook 109 is fixed to the mother line 104 floating in parallel with the sea surface. Hanging, it is a way to cultivate the seed pad attached to the shell 111 made of oyster shell, scallop shell or oyster shell-shaped plastic, etc. fitted to the droop 109.

At this time, the anchor line 103 is for fixing the continuous drop-type proton 100, the rich 101 is for generating buoyancy in the proton (100).

FIG. 2 illustrates a raft trainer 200 according to the prior art, and as shown in FIG. 2, the raft trainer 200 includes a plurality of transverses 201 and 203 intersected at an appropriate interval. A rich man 207 is attached to the raft 205, which is floated on the sea surface, and a plurality of hooks 209 are hung in the transverse direction 201 and 203 in the longitudinal direction, and the oysters are fitted in each hook 209. It is a benign group that cultivates seed plaques attached to shells 211 made of shells and the like.

However, when a shell such as a oyster shell with a seed pad produced according to the prior art is cultured by a continuous dropper type raft or a raft drop type cultivator, etc. After the formation of the oysters, each oyster needs to be separated. Therefore, it takes a lot of time and manpower to separate the oysters.

In addition, the shellfish meat growth value according to the prior art to be installed in the sea, there is a problem that the installation is inconvenient, unprotected against typhoons or other disasters.

An object of the present invention is to provide a shellfish breeding system to form a seawater passage so that seawater flows into the land, and to arrange shellfish breeding module to grow shellfish in the seawater passage, which is easy to grow shellfish and realizes free circulation of seawater. There is this.

One aspect of the present invention is a seawater passage connected to the coast so that seawater can be supplied; A reservoir for storing sea water introduced through the sea channel; A shellfish growing module separated through the reservoir and the separating wall, wherein the shellfish is grown, and the shellfish growing module includes a tank in which shellfish is grown; A tank installation unit in which a plurality of tanks are arranged; A seawater supply unit communicating with the dividing wall to supply seawater to the water tank installation unit; Seawater recovery unit for recovering the seawater passing through the water tank; A recycling unit for supplying the seawater recovered by the seawater recovery unit back to the water storage tank through a pump; It provides a shellfish growing system including a drain for discharging the seawater recovered through the seawater recovery unit to the outside.

Here, a connection pipe connecting the reservoir and the sea channel to be supplied with sea water is disposed, and the separation wall may further include a flow regulating gate for adjusting the amount of sea water supplied to the sea water supply unit.

In addition, the sea water supply unit is disposed between the water tank and the water tank installation portion flow rate adjustment gate for adjusting the supply amount of sea water; It includes a seawater supply path for flowing the seawater supplied from the flow regulating gate between a plurality of the water tank installation portion, wherein the seawater supply path is formed to be inclined so that the sea water flows from the flow rate adjustment gate to the water tank installation portion by the height difference Can be.

In addition, the water tank installation portion may be formed inside the seawater recovery portion.

In addition, the tank includes a tank body formed with a sea water inlet so that the sea water stored in the tank installation portion can be introduced; It may be installed in the water tank body, and installed at a position higher than the sea water inlet may include a recovery pipe for supplying the sea water inside the water tank body to the sea water recovery unit.

In addition, the seawater recovery unit is a plurality of seawater recovery passage formed long to recover the seawater from a plurality of tanks; And a seawater guide path for receiving seawater from the plurality of seawater recovery paths and supplying seawater to the recycling unit, wherein the seawater discharged from the water tank flows into the seawater guideway by a difference in height. It may be formed to be inclined.

The seawater guide may include a first seawater guide that connects the plurality of seawater recovery channels; And a second seawater guideway connecting the first seawater guideway and the recycling part, and the first and second seawater guideways may be formed to be inclined to allow seawater to flow by height difference.

On the other hand, the recycling unit for storing the seawater recovered through the seawater recovery unit; A regeneration water passage for connecting the regeneration storage tank and the water storage tank to flow seawater; And a pump for pumping the seawater of the regeneration storage tank into the regeneration water passage, and the regeneration water passage may be formed to be inclined so that the seawater may flow into the reservoir by the difference in height.

In addition, gravel is disposed below the regeneration water passage, a flow regulating gate for adjusting the flow rate of the recovered seawater is further disposed between the regeneration storage tank and the seawater recovery unit, and the drainage unit may be disposed in the regeneration storage tank. have.

Another aspect of the present invention is a seawater passage connected to the coast so that seawater can be supplied; A reservoir for storing sea water introduced through the sea channel; A shellfish growing module separated through the reservoir and the separating wall, wherein the shellfish is grown, and the shellfish growing module includes a tank in which shellfish is grown; A tank installation unit in which a plurality of tanks are arranged; A seawater supply unit which is formed to be inclined so that seawater may flow by a height difference, and communicates with the dividing wall to supply seawater to the water tank installation unit; A seawater recovery unit configured to be inclined so that the seawater passing through the water tank is moved by a height difference; A recycling unit pumping the seawater recovered by the seawater recovery unit through a pump and supplying the seawater back to the water storage tank; It provides a shellfish growing system including a drain for discharging the seawater recovered through the seawater recovery unit to the outside.

The shellfish development system according to the present invention is provided with seawater by forming a sea channel on the ground, it is possible to receive the seawater more smoothly, and thereby there is an effect that can prevent the death that can occur in the shellfish development process.

In addition, the shellfish growing system according to the present invention has the effect that can grow a large number of shellfish without the power to pull seawater to the ground because the seawater is supplied from the sea channel formed on the ground.

In addition, the shellfish growing system according to the present invention has the effect of minimizing the use of power due to the movement of seawater because the seawater flows using the ramp formed in the shellfish growing module.

In addition, the shellfish growing system according to the present invention maximizes the movement path of seawater, so that it is possible not only to realize a natural purification effect during the movement of seawater, but also to promote the growth of microorganisms that feed the shellfish during the movement of seawater. have.

3 is a plan view showing a sea channel according to an embodiment of the present invention, Figure 4 is a plan view of a shellfish growing system according to an embodiment of the present invention, Figure 5 is a cross-sectional view of the tank shown in FIG.

As shown, the shellfish breeding system according to the present embodiment is a seawater passage 10 connected to the coast so that the sea water can be supplied, and the reservoir 20 for storing the seawater introduced through the seawater passage 10, It is separated through the reservoir 20 and the dividing wall 25 and includes a shellfish growing module 30 to grow shellfish.

The shellfish-growing module 30 communicates with the tank 40 in which the shellfish is grown, the tank installation part 50 in which a plurality of the tanks are arranged, and the separation wall 25, and the seawater in the tank installation part 50. Supply the seawater supply unit 60 for supplying the seawater, the seawater recovery unit 70 for recovering the seawater passing through the water tank 40, and the seawater recovered in the seawater recovery unit 70 to the water storage tank 20 again. And a recycling unit 80 for discharging the seawater recovered through the seawater recovery unit 70 to the outside.

The shellfish may include oysters, shellfish or abalone.

The sea channel 10 is a water channel artificially formed by the user in the interstitial or reclaimed land in contact with the coast, the sea water is communicated through the sea channel 10, the sea channel 10 is a rice field adjacent to the sea or river Can be used in conjunction with wetlands.

The reservoir 20 is a space for storing sea water, and is connected to the sea channel 10 and a connection pipe 12 to receive sea water.

In addition, a pump (not shown) may be disposed in the connection pipe 12 connecting the sea channel 10 and the reservoir 20 to force the seawater of the sea passage 10 to the reservoir.

The water tank 40 is for raising shellfish, and a plurality of water tanks are installed in the water tank installation unit 50, and the worker is configured to separate only the water tank 40 from the water tank installation unit 50.

The water tank 40 includes a water tank body 42 configured to allow sea water to flow from the lower side, and a recovery pipe 44 connected to an upper side of the water tank body 42 and connected to the sea water recovery unit 70. It is composed.

The water tank body 42 is formed in a cylindrical shape formed of a synthetic resin material, such as FRP (fiber glass reinforced plastic) in the present embodiment, the sea water in the lower side to adjust the height of the sea water in accordance with the sea water of the water tank installation portion 50 Inlet 43 is formed. The seawater inlet 43 is a mesh 41 of the mesh form is disposed to prevent the shellfish from being discharged.

The recovery pipe 44 passes through the tank body 42 and is connected to the seawater recovery unit 70, and when the seawater height of the tank body 42 is higher than the recovery pipe 44, the recovery pipe 44 The seawater inside the tank body 42 through 44 is configured to flow to the seawater recovery unit 70.

Here, the tank body 42 side end of the recovery pipe 44 is formed to be bent upward, thereby preventing the shellfish food or shellfish in the tank body 42 to flow out.

The water tank installation unit 50 is a space in which the plurality of water tanks 40 are arranged. In this embodiment, the inner space of the seawater recovery unit 70 is formed as the water tank installation unit 50.

The sea water supply unit 60 is for supplying the sea water of the water tank 20 to the water tank 40 and the water tank installation unit 50, and is disposed between the water tank 20 and the water tank installation unit 50. A flow regulating gate 62 for adjusting a supply amount of sea water, a sea water supply path 64 for flowing sea water supplied from the flow regulating gate 62 between the plurality of tank installation units 50, and the sea water supply path Sea water supply pipe (66) for connecting the sea water of (64) to the respective tank installation unit (50).

The flow regulating gate 62 may be installed manually or automatically. In this embodiment, the water level sensor (not shown) and the flow regulating gate 62 for detecting a water level in the water tank installation unit 50 are moved. It is configured to be automatically adjusted through a power unit (not shown).

In this embodiment, the water tank installation unit 50 is arranged in a row to the left / right on both sides of the sea water supply path 64, the sea water supply path 64 through the water tank installation unit 50 Is placed.

The sea water supply pipe 66 is connected to the sea water supply path 64 and is disposed to be supplied to each of the tank installation units 50 by the inclination.

The seawater recovery unit 70 is a seawater recovery path 72 formed along the plurality of water tanks 40, and a seawater guide path for guiding the seawater recovery paths 72 to the recycle unit 80 ( 74, wherein the seawater guide path 74 includes a first seawater guide path 74a connecting the plurality of seawater recovery paths 72, and the first seawater guide path 74b to the recycling unit 80. ) Is connected to the second seawater guide path (74b).

Here, the seawater guide path 74 is configured to allow the seawater discharged to the water tank 40 to flow naturally through the inclination so that the seawater can be circulated without a separate power.

So, in the present embodiment, the height of the seawater recovery portion 70 is formed lower than the recovery pipe 44.

The recycling unit 80 connects the regeneration storage tank 82 in which the seawater introduced through the seawater recovery unit 70 is stored, and the regeneration storage tank 82 and the second seawater guide path 74b. Flow regulating gate 84 for adjusting the flow rate flowing into the reservoir 82, the regeneration water passage 86 for connecting the regeneration storage 82 and the reservoir 20, and the seawater of the regeneration storage 82 And a pump 88 pumping into the regeneration channel 86.

The regeneration storage tank 82 is a space for storing sea water.

The flow regulating gate 84 is controlled to open and close according to the height of the sea water stored in the regeneration storage tank 82, which can be automatically performed by a motor and a water level control sensor (not shown).

The regeneration channel 86 is for natural purification of organic matter contained in seawater, and is formed to be inclined at a predetermined angle, and is disposed with pebbles at a lower side, and the size of the pebbles is 1cm to 5cm in diameter. Thus, when the seawater flows in the regeneration water channel 86 in which the gravel is disposed, the floating water or organic matter is precipitated between the gravel so that the seawater is naturally purified by the filter action. And the end of the regeneration channel 86 is connected to the reservoir (20).

The pump 88 is for vertically pumping the seawater of the regeneration storage tank 82 to the regeneration water passage 86, and the configuration of the pump 88 is a general fact to those skilled in the art, and thus detailed description thereof will be omitted. .

The drainage path 90 is formed in the regeneration storage tank 82, and discharges the stored seawater to the outside according to the user's selection to prevent the water flow into the reservoir 20.

Hereinafter, the operation of the shellfish rearing system according to the present embodiment will be described in more detail with reference to the accompanying drawings.

First, the seawater supplied through the seawater passage 10 is stored in the reservoir 20 through the connection pipe 12, and the seawater stored in the reservoir 20 is supplied to the seawater supply passage 64 through the flow regulating gate 62. The seawater supplied to the seawater supply path 64 is supplied to each tank installation unit 50 through the seawater supply pipe 66.

Here, the flow of the seawater to the flow regulating gate 62, the seawater supply path 64 and the seawater supply pipe 66 flows in the direction of gravity due to the height difference.

In particular, the seawater supply unit 60 may be installed in addition to the food supply for supplying the food of shellfish, and can be fed to each tank installation unit 50 in accordance with the movement of the seawater, through each The operator does not have to move to feed the water for each tank installation unit 50.

And the sea water supplied to the water tank installation unit 50 is to raise the water level of the water tank installation unit 50, through this through the sea water inlet 43 formed on the lower side of the water tank 40 into the water tank 40 After being introduced, if the water level inside the water tank body 42 is formed higher than the recovery pipe 44, the water flows to the seawater recovery unit 70 through the recovery pipe 44.

The seawater recovery unit 70 is formed to be inclined so that seawater flows naturally, and the seawater dropped through the recovery pipe 44 flows to the seawater guideway 74 through the seawater recovery path 72. The recycling unit 80 is guided.

Thereafter, the seawater flowing to the recycling unit 80 is moved to the regeneration water channel 86 at a high position through the pump 88, and flows to the water storage tank 20 along the ramp formed in the regeneration water channel 86. .

As described above, the shellfish breeding system according to the present embodiment installs the water tank 40 on the land so that the management of the worker can be easily carried out, and the seawater is pulled through the sea channel 10 to the land to use the large-scale water supply. No power required.

In addition, the seawater stored in the reservoir 20 is flowed to the seawater supply unit 60, the water tank installation unit 50 and the seawater recovery unit 70 by the difference in the height of the seawater can smoothly flow seawater without additional power.

In addition, by pumping the seawater into the regeneration water passage 86 having a high position through the pump 88 of the recycling unit 80, the seawater is freely circulated according to the potential energy.

In addition, the shellfish development system according to the present embodiment includes a reservoir 20, a seawater supply passage 64, a seawater recovery passage 72, first and second seawater guide passages 74a, 74b, and a regeneration channel 86. Since the seawater flows through it, it is possible to secure the growth time of the microorganisms according to the movement of seawater, and through this, it is possible not only to naturally feed the shellfish's food, but also to purify the seawater by increasing the seawater's moving distance.

The present invention is not limited to the embodiments and drawings presented herein, and can be applied by those skilled in the art within the scope of the technical idea of the present invention.

1 is a perspective view showing a continuous drop-type proton according to the prior art

Figure 2 is a perspective view of a raft type trainer according to the prior art

3 is a plan view showing a sea channel according to an embodiment of the present invention

4 is a plan view of the shellfish growing system according to an embodiment of the present invention

5 is a cross-sectional view of the water tank shown in FIG.

<Brief description of the symbols for the main parts of the drawings>

10: seawater 20: reservoir

30: shellfish development module 40: tank

50: water tank installation unit 60: sea water supply unit

70: seawater recovery section 80: recycling section

90 drain

Claims (17)

Sea channels connected to the coast to provide seawater; A reservoir for storing sea water introduced through the sea channel; It is separated through the water tank and the separation wall and includes a shellfish growing module that grows shellfish, The shellfish development module A tank in which shellfish are grown; A tank installation unit in which a plurality of tanks are arranged; A seawater supply unit communicating with the dividing wall to supply seawater to the water tank installation unit; Seawater recovery unit for recovering the seawater passing through the water tank; A recycling unit for supplying the seawater recovered by the seawater recovery unit back to the water storage tank through a pump; Shellfish growing system including a drain for discharging the seawater recovered through the seawater recovery unit to the outside. The method according to claim 1, Shellfish development system is arranged that the connecting pipe connecting the reservoir and the sea channel so that sea water is supplied. The method according to claim 1, Shellfish rearing system is further disposed on the partition wall is a flow control gate for controlling the amount of seawater supplied to the seawater supply unit. The method according to claim 1, The sea water supply unit A flow regulating gate arranged between the reservoir and the tank installation unit to adjust a supply amount of seawater; Shellfish breeding system comprising a seawater supply passage for flowing the seawater supplied from the flow regulating gate between a plurality of the tank installation portion. The method according to claim 4, The seawater supply passage is a shellfish growing system formed inclined so that the seawater flows by the height difference from the flow regulating gate to the water tank installation portion. The method according to claim 1, The tank installation portion shellfish growing system formed inside the seawater recovery portion. The method according to claim 1, The tank A water tank body formed with a sea water inlet so that the sea water stored in the water tank installation portion can be introduced; And a recovery pipe installed in the tank body and installed at a position higher than the sea water inlet so as to supply the seawater inside the tank body to the seawater recovery unit. The method according to claim 1, The seawater recovery unit A plurality of seawater recovery passages formed long to recover seawater from the plurality of tanks; Shellfish development system comprising a seawater guide for receiving seawater from the plurality of seawater recovery passage to supply seawater to the recycling unit. The method according to claim 8, And the seawater recovery passage is formed to be inclined so that the seawater discharged from the water tank may flow into the seawater guide path due to the difference in height. The method according to claim 8, The seawater guide route comprises: a first seawater guide passage connecting the plurality of seawater recovery passages; Shellfish development system comprising a second seawater guide connecting the first seawater guide and the recycling unit. The method according to claim 10, The first and second seawater guide path is a shellfish growing system formed to be inclined so that seawater can flow by the height difference. The method according to claim 1, The recycling unit A regeneration storage tank for storing the seawater recovered through the seawater recovery unit; A regeneration water passage for connecting the regeneration storage tank and the water storage tank to flow seawater; Shellfish breeding system comprising a pump for pumping the seawater of the regeneration storage tank to the regeneration water. The method according to claim 12, The regeneration channel is a shellfish development system formed to be inclined so that the seawater flows to the reservoir by the height difference. The method according to claim 12, Shellfish rearing system in which gravel is disposed below the regeneration channel. The method according to claim 12, Shellfish development system further comprising a flow regulating gate for adjusting the flow rate of the seawater recovered between the regeneration storage tank and the seawater recovery unit. The method according to claim 12, Shellfish rearing system in which the drain portion is disposed in the regeneration storage tank. Sea channels connected to the coast to provide seawater; A reservoir for storing sea water introduced through the sea channel; It is separated through the water tank and the separation wall and includes a shellfish growing module that grows shellfish, The shellfish development module A tank in which shellfish are grown; A tank installation unit in which a plurality of tanks are arranged; A seawater supply unit which is formed to be inclined so that seawater may flow by a height difference, and communicates with the dividing wall to supply seawater to the water tank installation unit; A seawater recovery unit configured to be inclined so that the seawater passing through the water tank is moved by a height difference; A recycling unit pumping the seawater recovered by the seawater recovery unit through a pump and supplying the seawater back to the water storage tank; Shellfish growing system including a drain for discharging the seawater recovered through the seawater recovery unit to the outside.

Images