KR20170077610A - A high density cycle filtration cultivation apparatus - Google Patents

Abstract

The present invention relates to a culture plant by a high-density circulation filtration method, and it is intended to provide an environment suitable for culturing various kinds of seafood such as fishes and shellfishes and for living in seafood.
The culture plant by the high density circulation filtration system according to the present invention comprises a water collection unit having a hollow space for storing and feeding seawater therein, a seawater circulation unit for sucking and filtering seawater of the water collection unit, And a nutrient component supply unit for supplying nutrient components.

Description

{A HIGH DENSITY CYCLE FILTRATION CULTIVATION APPARATUS}

The present invention relates to a culture field by a high-density circulation filtration method.

In general, in the case of fish, shellfish, etc., in the case of the water-based aquaculture, firstly, in order to keep the dissolved oxygen value of the aquaculture tank at an appropriate value, The amount of dissolved oxygen is maintained at an appropriate level. The feed is fed to the fish, the remaining feed consumed by the fish, and the excrement excreted by the fish are discharged to the outside together with the outflowed effluent.

However, since a large amount of aquaculture is continuously inflowed and discharged, it takes a large amount of energy for the influx of the aquaculture water as well as the shortage of water, and the decay of the remaining feeds administered to the fish and the disruption of fish growth Ammonia nitrogen is generated in the effluent, which is discharged to the outside together with the effluent, thereby contaminating the water system.

Patent Registration No. 10-0981601 (2010.09.06)

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a high-density circulation system capable of easily culturing various kinds of seafood such as fishes and shellfishes at high density, The purpose of this is to provide the farms by filtration method.

The present invention relates to a high density circulation filtration system for a seawater storage and rearing system, comprising: a water collection unit having a hollow space for storing and feeding seawater therein; a seawater circulation unit for sucking and filtering seawater of the water collection unit, And a nutrient component supply unit for supplying the nutrient component to the user.

Further, the seawater circulation unit includes:

A pump for sucking the seawater stored in the receiving portion and then supplying the collected seawater to the receiving portion; and a filter connected to the pump for filtering the seawater transferred through the pump to supply the filtered seawater to the inside of the receiving portion.

And an auger portion provided at the water receiving portion to be spaced apart from each other and injecting bubbles into the water while reciprocating in respective designated intervals,

In the aeration unit,

A drum which is respectively installed in the first and second driving parts and is rotated in place by receiving power from the first and second driving parts, , An air transmission part having one side protruding to the outside of the drum and the other side passing through the inside of the water receiving part, an air transmission part provided to the water reception part and protruding to the outside of the drum, And an air discharging unit located inside the receiving unit and discharging the air transferred through the air transmitting unit to the seawater while being moved by the air transmitting unit wound or unwound from the drum.

In addition, a protective frame provided with an opening and closing part for opening and closing the inlet port, a protective frame for opening and closing the inlet port, a protective frame for opening and closing the inlet port, A shell formed of openings formed in openings of the frame to prevent intrusion of predatory fish species into the inner space of the protective frame, and shells provided at intervals in the protective frame, Including the form part,

In the form part, a plurality of discharge holes capable of discharging seawater are formed to pass upward and downward when drawn out to the upper part of the water receiving part.

And a sterilizing unit for removing and sterilizing ammonia nitrogen contained in seawater supplied from the seawater circulation unit through an electrolysis reaction.

The high density circulation filtration system according to the present invention improves the quality of seawater stored in the water collecting part, and thus it is possible to cultivate various types of seafood such as fishes and shellfishes with high density and easily, and is suitable for living in seafood Environment can be provided.

Brief Description of the Drawings Fig. 1 is a diagram showing a culture field by a high-density circulation filtration method according to the present invention.
FIG. 2 is a view showing the operation of the aeration unit applied to a farm site by the high-density circulation filtration system according to the present invention.
3 is a plan view showing the operation of the aeration unit applied to the farm by the high-density circulation filtration system according to the present invention.
FIG. 4 is a view showing a nutrient supply unit applied to a farm in a high density circulation filtration system according to the present invention; FIG.
5 is a perspective view showing a shellfish culture unit applied to a farm by a high density circulation filtration method according to the present invention.
6 is a view showing an internal state of a shellfish culture unit applied to a farm in a high density circulation filtration system according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

2 is a view showing the operation of the aeration unit applied to the farm by the high-density circulation filtration method according to the present invention, and Fig. 3 is a view showing the operation of the aeration unit according to the present invention. FIG. 4 is a view showing a nutrient supply unit applied to a farm in a high density circulation filtration system according to the present invention, and FIG. 5 is a view FIG. 6 is a view illustrating an inner state of a shellfish culture unit applied to a farm by a high-density circulation filtration system according to the present invention, and FIG. 6 is a view illustrating an internal state of a shellfish culture unit applied to a farm.

1 to 6, a culture plant 1 according to the present invention has a water tank 10, a seawater circulation unit 20, a sterilizing unit 60, a nutrient supply unit 30 ).

The water receiving portion 10 is open at the top and has a hollow space therein to store seawater and to produce various species of fish, shellfish, diatoms and algae at high density.

The water receiving portion 10 may be formed in various shapes such as a circular shape or a rectangular shape and a through hole through which the aeration portion 40 and the seawater circulation portion 20 to be described later can pass is formed on the upper side and the lower side of the side wall do.

At this time, the culture plant 1 by the high density circulation filtration method according to the present invention can be used on the land or sea, and when used in the sea, the water receiving section 10 is formed of a material having buoyancy.

The seawater circulation unit 20 sucks seawater from the water receiving unit 10 and filters and circulates the seawater. The seawater circulation unit 20 is further divided into a pump 21 and a filtration unit 22.

The pump 21 sucks the seawater stored in the water receiving unit 10 and the sucked seawater sequentially passes through the filtering unit 22 and the sterilizing unit 60, .

At this time, a valve (not shown) is installed in the connection hose 211 connecting the water receiving unit 10 and the filtration unit 22 to discharge or block the seawater in the water receiving unit 10.

The filtration unit 22 is connected to the pump 21 through a connection hose 212 and removes solid matter before the seawater sucked by the pump 21 passes through the sterilizing unit 60.

Then, the seawater from which the solids are removed is conveyed to the sterilizing section 60 by the pump 21.

The sterilizing unit 60 supplies the seawater through the pump 21 and sterilizes the sterilized water.

Specifically, an empty space into which the seawater supplied from the seawater circulation unit 20 flows is formed inside the sterilizing unit 60.

A cathode electrode portion (not shown) to which cathode power is applied and an anode electrode portion (not shown) to which anode power is applied are formed in the empty space of the sterilizing portion 60 so that an electrolytic reaction may occur in the flowing seawater Is installed.

In addition, the sterilizing unit 60 supplies an anode power source and an anode power source by a DC voltage control unit (not shown) and a DC power supply unit (not shown) to cause an electrolytic reaction to remove and sterilize ammonia nitrogen contained in seawater do.

The sterilized seawater is supplied to the inside of the water receiving unit 10 through the transfer pipe 61 through the pumping force of the pump 21.

The nutrient supply part 30 supplies the nutrients to the fishes and shellfish in the water receiving part 10 and supplies the nutrients to the feeding hopper 31, the motor 32, the screw 33, Respectively.

At this time, the nutrient component may be phytoplankton or steelmaking slag generally used in a farm.

The supply hopper 31 is positioned above the open part of the water receiving part 10 and flows the nutrients into the water receiving part 10.

Further, a nozzle for quickly discharging nutrients is further provided at a lower outlet of the supply hopper 31.

The motor 32 is provided on the upper side of the supply hopper 31 to provide rotational power to the screw 33.

The motor 32 may be a known AC motor or a DC motor, and the motor shaft is rotated in a forward direction or a reverse direction.

The screw 33 is vertically installed in the inner space of the supply hopper 31 and the upper end of the rotating shaft 331 is connected to the motor shaft of the motor 32.

That is, the screw 33 is rotated in place through the motor 32 to apply pressure to the inside of the supply hopper 31, so that the nutrient is quickly discharged into the interior of the water receiving portion 10 through the nozzle To fish and shellfish.

At this time, the motor 32 and the screw 33 may be omitted, and the nutrient supply part 30 may be formed only by the supply hopper 31.

The water receiving unit 10 is provided with a plurality of air vent portions 40 spaced apart from each other to supply fine air bubbles by supplying air to seawater.

Specifically, the aeration unit 40 is divided into first and second driving units 41 and 42, a drum 43, an air delivery unit 44, an air supply unit 45, and an air discharge unit 46.

As shown in FIGS. 1 and 3, the first and second driving units 41 and 42 are installed symmetrically in the left and right directions on the upper end of the water receiving unit 10.

The first and second driving units 41 and 42 may be known AC motors or DC motors, and the motor shaft may be rotated in a forward or reverse direction.

The motor shafts of the first and second driving portions 41 and 42 are directed to the outside of the water receiving portion 10.

The drum 43 guides winding or unwinding of the air transfer unit 44 and is installed on the motor shaft of the first driving unit 41 and the motor shaft of the second driving unit 42, 2 drive unit 41, 42, and is wound or unwound around the outer periphery of the air delivery unit 44 while being rotated in place.

In this case, the first and second driving units 41 and 42 are operated through a control unit (not shown), and the motor shaft of the first driving unit 41 is rotated in a direction in which the air transmitting unit 44, The motor shaft of the second driving unit 42 is rotated in the direction in which the air transmission unit 44 is wound on the drum 43. [

When the motor shaft of the first driving part 41 is rotated in the direction in which the air transmitting part 44 is wound on the drum 43, the motor shaft of the second driving part 42 is rotated by the air transmitting part 44, (43).

In addition, it is noted that a roller (not shown) may be installed on the outer wall of the water receiving portion 10 to smoothly wind and unwind the air transmitting portion 44.

The air transfer unit 44 transfers air to the air discharge unit 46 while moving the air discharge unit 46 to be described later from the bottom surface of the water receiving unit 10, The hose may be formed by a hose formed with a furnace.

The upper portion of the air transfer portion 44 is wound or unwound on the drum 43 and the lower portion of the air transfer portion 44 is connected to the air discharge portion 46 through a through hole formed in a lower side of the side wall of the water receiving portion 10.

An upper portion of one of the air transmission portions 44 protrudes to the outside of the drum 43 and is connected to the air supply portion 45.

The air supply unit 45 supplies air to the inside of the air discharge unit 46. The air supply unit 45 is located outside the water receiving unit 10, (43).

The air supply unit 45 may be formed by a known air supply unit and supplies air to the inside of the air discharge unit 46 through an air passage of the air transfer unit 44.

At this time, the operation of the first and second driving units 41 and 42 is controlled by a control unit (not shown).

The air discharge unit 46 discharges air to the seawater stored in the water receiving unit 10 and may be formed into a cylindrical shape or a rectangular box block shape and a plurality of air discharge holes 461 are spaced apart from each other .

The air discharge unit 46 is moved by the air transfer unit 44 wound or unwound on the drum 43 while being positioned on the inner bottom surface of the water receiving unit 10, The delivered air is discharged to seawater.

That is, as shown in FIG. 1, the first driving unit 41 positioned on the left side through the control unit (not shown) causes the drum 43 to operate in the direction of winding the air transmitting unit 44, The second discharging portion 42 is moved to the left side of the water receiving portion 10 when the drum 43 is operated in the direction of unwinding the air transmitting portion 44, The first driving part 41 causes the drum 43 to operate in the direction to unwind the air delivering part 44 and the second driving part 42 positioned on the right side causes the drum 43 to move to the air transmitting part 44 The air discharge unit 46 is moved to the right side of the water receiving unit 10 and the air discharge unit 46 is moved in the left and right direction, The air can be supplied to the air discharge unit 46 through the air transfer unit 44 in a straight line.

3, a plurality of air vent portions 40 are provided at intervals in the water receiving portion 10, and each of the air vent portions 46 is connected to the water receiving portion 46, Air can be uniformly supplied to the sea water while reciprocally moving the water receiving portion 10, and it is possible to provide an environment suitable for living in fishes, shellfishes, etc. living in the water receiving portion 10.

In addition, the culture plant 1 by the high-density circulation filtration method according to the present invention can improve the quality of seawater through the sterilizing unit 60 and the aeration unit 40 described above, Diatoms and seaweeds can be easily cultured at high density.

Meanwhile, a shell forming unit 50 is further installed inside the water receiving unit 10.

The shellfish form part 50 is further divided into a protection frame 51, a needle entrance part, and a form part 53.

The protection frame 51 may be formed in a substantially rectangular box shape and may have a predetermined width and length, and a hollow space for encapsulation may be formed therein.

Each edge of the protective frame 51 may be open for inflow of seawater.

On both inner side walls of the protective frame 51, seating tabs 512 are formed to be spaced from each other along the upward and downward directions so that the receiving portion 53 to be described later can be installed.

The protective frame 51 is drawn into the lower part of the water receiving part 10 through the elevating part 70 and is then immersed in seawater or drawn out to the upper part of the water receiving part 10.

The elevating unit 70 is further divided into a motor 71, a drum 72, and a wire 73.

The motor 71 is located outside the water receiving part 10 and may be an AC motor or a DC motor.

The motor shaft of the motor 71 is rotated in the forward direction or the reverse direction to elevate the protection frame 51.

The drum 72 is installed on the motor shaft of the motor 71 and receives power from the motor shaft of the motor 71 to be rotated so that the wire 73 is wound on the outer circumference or unwound.

An upper portion of the wire 73 is fixed to the drum 72 and a lower portion of the wire 73 is fixed to the upper side of the protective frame 51.

At this time, a coupling ring (not shown) is formed on the protection frame 51 so that the wire 73 can be coupled.

The motor 71 may be controlled through a control unit (not shown) for controlling the first and second driving units 41 and 42 and the air supply unit 45. The manager may control the motor 71 It is possible to insert a shellfish to be cultivated in the inside of the protective frame 51 by taking the protective frame 51 down or raising it, or to take out the shellfish that has grown to a certain size or more.

On the one hand side of the protective frame 51 there is provided a receiving part 511 for providing a food part 53 to be described later or for feeding food to the shellfish and the charging part 51 is provided with the charging part 511 An opening / closing part 513 for opening / closing is provided so as to be rotatable through a hinge 514.

At this time, the charging port 511 and the opening / closing part 513 may be formed on the upper side or the lower side of the protection frame 51.

That is, the inlet 511 and the opening / closing part 513 can easily feed the shellfish and can be installed in a portion where the shell 53 can be easily installed.

The intrusion preventing portion 52 is installed at each open portion of the protective frame 51.

The intrusion prevention part 52 is a part of the mesh-shaped wire mesh or the synthetic mesh network so that seawater can pass through the intrusion prevention part 52 while preventing predatory fish species such as rocky beaches, snowshoe, lobster, eel, Or may be formed by one.

The form part 53 is accommodated in the protective frame 51 and both sides thereof are seated and supported on the upper end of the seating step 512.

At this time, the forming unit 53 may be bolted to the seating jaw 512 so as not to float by the seawater.

A plurality of discharge holes 531 penetrating in the upward and downward directions are spaced apart from each other by a predetermined distance and the shell forming unit 50 is raised to the outside of the hatching unit 10 The seawater can be automatically discharged to the outside of the protective frame 51 and the seawater can be automatically introduced into the protective frame 51 when the shell forming unit 50 is lowered to the lower side of the water receiving unit 10 can do.

When the shell forming unit 50 is raised to the outside of the receiving unit 10, the seawater can be automatically discharged to the outside of the protecting frame 51, You can manage it.

Since the inner space of the protecting frame 51 is partitioned into a plurality of spaces by the forming unit 53, the shell forming unit 50 described above can form a large amount of shellfish and can easily manage the shellfish .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

1: Cultivation by high density circulation filtration
10: Water receiving section 20: Seawater circulation section
21: Pump 211, 212: Connection hose
22: Filtration section 30: Nutrient supply section
31: feed hopper 32, 71: motor
33: screw 331:
40: width base portion 41: first driving portion
42: second driving part 43, 72: drum
44: air delivery part 45: air supply part
46: air discharge part 461: air discharge hole
50: shellfish form part 51: protection frame
511: Inlet port 512:
513: opening and closing part 514: hinge
52: Intrusion prevention part 53:
531: Discharge hole 60: Sterilization part
61: Feed pipe 70:
73: Wire

Claims (5)

A water supply portion having an empty space for storing and feeding seawater therein,
A seawater circulation unit for sucking, filtering and circulating seawater in the water receiving unit,
And a nutrient component supply unit for supplying nutrients to the seawater stored in the water receiving unit. The method of claim 1,
The seawater circulation unit,
A pump for sucking the seawater stored in the receiving unit and supplying the seawater to the receiving unit,
And a filtration unit connected to the pump and filtering the seawater transferred through the pump to supply the filtered seawater to the inside of the water receiving unit. The method of claim 1,
And an auger part installed at the water receiving part at intervals and injecting bubbles into water while being reciprocated in respective designated sections,
In the aeration unit,
A first and a second driving units installed to be symmetrical with respect to the water receiving unit,
A drum disposed in each of the first and second driving units and adapted to receive power from the first and second driving units and rotated in place,
An air transmission portion which is wound or pulleyed on the drum, one side of which protrudes to the outside of the drum and the other side of which penetrates into the inside of the water receiving portion,
An air supply unit connected to an air transmission unit installed on the water receiving unit and protruding to the outside of the drum and supplying air into the air transmission unit,
And an air discharging portion located inside the receiving portion and discharging the air transferred through the air transmitting portion while being moved by the air transmitting portion wound or unwound on the drum to the seawater. The method of claim 1,
A protection frame provided with an opening and closing part for opening and closing the feeding port, a feeding port for feeding the food of the shellfish to one side of the feeding frame,
An intrusion preventing part installed at each opening part of the protection frame and preventing the predation fish from entering into the inner space of the protection frame,
And a shell forming unit which is installed at a distance from each other in the protective frame and comprises a habitat for allowing shellfish to live there,
The culture unit comprises a high density circulation filtration system in which a plurality of discharge holes capable of discharging seawater are drawn upwardly and downwardly when being drawn to the upper part of the water receiving unit. The method of claim 1,
And a sterilizing unit for removing and sterilizing ammonia nitrogen contained in seawater supplied from the seawater circulation unit through an electrolysis reaction.

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