KR20160144769A - Recirculating rearing system - Google Patents

Abstract

The present invention relates to a circulatory filtration-type farming system. The circulatory filtration-type farming system comprises: a pump (17) sucking breed water from a farming water tank (11) by pumping; a plurality of venturis (18) mixing air or oxygen into the breed water pumped by the pump (17); an oxygen dissolver (3) increasing solubility of oxygen by supplying and storing the oxygen-mixed breed water from the venturi (18) through a first pipe (L1); a heat pump (13) cooling or heating the breed water discharged from the oxygen dissolver (3) by supplying the same through a second pipe (L2); and a skimmer (5) removing organic substances using bubbles after being supplied with the air-mixed breed water from the venturi (18).

Description

{Recirculating rearing system}

The present invention relates to a circulating filtration system, and more particularly, to a circulating filtration system capable of efficiently circulating filtration of breeding water by improving the arrangement and structure of structures for supplying oxygen to breeding water, removing organic matter, Technology.

Generally, aquatic products such as fish are cultured in a water tank. In such a tank, breeding water is discharged through an outlet provided on the floor, and the discharged water is supplied to the tank after the purification treatment.

These aquaculture systems are used to grow fish in the aquarium, so they can be contaminated with toxic gases such as excrement from fish metabolism, feed residue remaining in water, ammonia, and secondary nitrogen generated from their decomposition have.

Therefore, in the aquaculture system, filtration of the stock water stored in the water tank is an important factor.

In addition, the aquaculture system is provided with a facility for purifying the quality of the breeding water supplied to the breeding tank, a facility for cooling or heating the breeding water, and a facility for supplying oxygen.

However, in such a conventional aquarium system, a water purification apparatus, a cooling and heating apparatus, an oxygen supply apparatus, and the like are independently installed, which requires a large space and also complicates the installation process.

Patent Application No. 10-1997-709942 (Name: Fish farming device)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above problems, and it is an object of the present invention to provide an apparatus and a method for improving the arrangement and structure of structures for supplying oxygen, removing organic matter, Which is capable of circulating and filtering the waste water.

In order to achieve the above-mentioned object, an embodiment of the present invention includes a pump 17 for sucking breeding water from a raising water tank 11 by pumping;

A plurality of venturi (18) for mixing oxygen or air with the breeding water pumped by the pump (17);

An oxygen dissolver 3 for increasing the solubility of oxygen by feeding and storing oxygen in the venturi 18 through a first pipe L1;

A heat pump 13 that is cooled or warmed by feeding the breeding water discharged from the oxygen dissolver 3 through the second pipe L2; And

And a skimmer (5) which is supplied with breeding water mixed with air in Venturi (18) to remove organic matter by bubbles.

As described above, the circulation filtration system according to the embodiment of the present invention has the following advantages.

First, the breeding water is pumped by the pump, then mixed with oxygen or air by passing through a venturi, and mixed water is supplied to the oxygen dissolver to increase the oxygen solubility. It is possible to easily circulate and filter the breeding water through a cycle of returning to the breeding tank.

Second, pumps, venturi, oxygen dissolver, skimmer, heat pump, warming tank, and cooling tank can be intensively arranged on one base by piping, and a plurality of pumps and venturi can be arranged in an oxygen dissolver and a skimmer The oxygen dissolver and the skimmer are separately connected to each other so that a narrow space can be utilized more effectively.

Thirdly, in the circulation of the breeding water, when more organic matter removal is required, it is supplied to the skimmer and treated, and when oxygen supply is necessary, it is supplied to the oxygen dissolving device and treated, thereby reducing the processing time and cost of the breeding tank.

Fourth, since not only circulation filtration of the breeding water but also the ground water can be used as the breeding water, it can be used as a deficiency of the breeding water.

1 is a perspective view schematically showing a circulation form system according to an embodiment of the present invention.
FIG. 2 is a side view schematically showing the structure of the circulating form system shown in FIG. 1. FIG.
FIG. 3 is a plan view showing the circulation form system shown in FIG. 1. FIG.
FIG. 4 is a schematic view showing a cooling tank and a warming tank disposed in the heat pump and the heat pump shown in FIG. 2. FIG.
FIG. 5 is a schematic view showing the structure of the venturi tube shown in FIG. 2. FIG.

Hereinafter, a circulating filtering style system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 5, the circulation filtration system 1 proposed by the present invention includes a pump 17 for pumping the breeding water from a breeding water tank 11 for culturing fish, A venturi 18 for mixing oxygen or air with the breeding water pumped by the pump 17; An oxygen dissolver (3) for storing the breeding water mixed with oxygen in Venturi (18) to increase the solubility of oxygen; A heat pump (13) for cooling or warming the breeding water discharged from the oxygen dissolver (3); And a skimmer (5) for removing organic matter by bubbles by supplying breeding water mixed with air in Venturi (18).

In the circulating filtration culture system having such a structure, the pump 17 sucks the breeding water stored in the breeding water tank 11 and supplies it to the Venturi 18. The pump 17 is connected to the breeding tank 11 at one end and connected to the venturi 18 at the other end.

Therefore, when the pump 17 is driven, the breeding water stored in the breeding water tank 11 can be sucked by the pressure difference and supplied to the venturi 18.

A plurality of such pumps 17 are provided, and their roles are divided into two. That is, a part of the pump 17 is connected to the venturi 18 for supplying the breeding water to the oxygen dissolver 3 and the rest is connected to the venturi 18 for supplying the breeding water to the skimmer 5 .

Therefore, the plurality of pumps 17 supply the breeding water to the oxygen dissolver 3 or supply the breeding water to the skimmer 5. Therefore, in the circulation of the breeding water, when more organic matter removal is required, it is supplied to the skimmer 5 to be treated, and when oxygen supply is necessary, it can be supplied to the oxygen dissolver 3 for treatment. At this time, the pump 17 and the venturi 18 are disposed between the oxygen dissolver 3 and the skimmer 5, so that the upper space of the base B can be efficiently utilized.

The venturi 18 generates a pressure difference due to the speed of the breeding water to be pumped, so that air in the air is sucked and mixed with the breeding water. One end 18a of the venturi 18 is connected to the pump 17 and the other end 18b of the Venturi 18 is connected to the first pipe L1 connected to the oxygen dissolver 3 or the skimmer 5. In the middle, a narrow channel is formed.

Therefore, a pressure difference occurs in the process of passing the breeding water sucked by the pump 17 through a relatively narrow channel, and air in the atmosphere can be introduced through the air pipe 19 due to the pressure difference.

In this process, the breeding water and air can be mixed with each other and supplied to the oxygen dissolver 3 or the skimmer 5 through the first pipe L1.

The breeding water discharged from the venturi 18 connected to the oxygen dissolver 3 is supplied to the oxygen dissolver 3 and the breeding water discharged from the Venturi 18 connected to the skimmer 5 is supplied to the skimmer 5).

The oxygen regulator 19 is connected to the venturi 18, so that the amount of air sucked into the Venturi 18 can be adjusted. At this time, the oxygen regulator 19 is connected to the venturi 18 by a pipe or the like, so that the amount of air sucked into the venturi can be controlled.

The oxygen dissolver 3 is formed with a space of a certain volume therein and can store the water supplied through the first pipe L1. In addition, the oxygen dissolver 3 may be used in various types of dissolvers 3,

For example, an oxygen dissolver 3 such as a falling-off type, a pipe injection type, and an air stone type can be used.

That is, in the case of the inverted Oxygen dissolver (3), water and oxygen are dissolved in water by using water pressure. The pipe injection method is a method of injecting oxygen into a water pipe. In addition, the air stone method is a method of directly introducing oxygen into a water tank by using a microporous stone.

The breeding water tank 11 having increased oxygen solubility by the oxygen dissolver 3 of this type is supplied to the heat pump 13 through the second pipe L2 so that the temperature can be cooled or warmed.

More specifically, the heat pump 13 evaporates the refrigerant in the evaporator E, takes the heat away from the evaporator E to become a gas, re-circulates the refrigerant through the condenser C, it means.

The heat pump 13 is provided with an evaporator E for cooling the cold water by bringing the refrigerant into a low-temperature / low-pressure gas state, and an evaporator E for compressing the low- A condenser C for warming the breeding water by producing high-pressure liquid-phase refrigerant by discharging the heat of the high-temperature / high-pressure refrigerant discharged from the compressor P to liquefy the refrigerant, and a condenser C And an expansion valve (V) that discharges the high-pressure liquid refrigerant discharged from the evaporator (E) to a low-temperature / low-pressure / liquefied refrigerant and discharges it to the evaporator (E).

The evaporator E is provided with a cooling tank 7 for storing and cooling the breeding water and a warming tank 9 for storing the breeding water in the condenser C.

In the heat pump 13, the refrigerant in the compressor P is in a gaseous state and is pressurized to a predetermined pressure or higher, so that the refrigerant can be brought into a high-temperature and high-pressure state so that condensation can be performed well.

The refrigerant compressed in the compressor P is supplied to the condenser C through the pipe, cooled by the external water or air in the condenser C, and changed from the gas to the liquid state. At this time, the refrigerant is liquefied, and the heat of condensation is discharged to the outside, thereby transferring heat to the surroundings.

Therefore, the heat transferred from the condenser C is transferred to the warming tank 9, thereby heating the breeding water.

The refrigerant that has passed through the condenser C is supplied to the expansion valve V through the pipe and expanded while passing through the expansion valve V, thereby lowering the pressure and temperature. Therefore, evaporation can be easily performed in the evaporator E as a post-process.

The refrigerant that has passed through the expansion valve (V) evaporates while passing through the evaporator (E) and changes into a gas to absorb the latent heat of evaporation from the outside.

Therefore, the breeding water of the cooling tank 7 disposed around the evaporator E can be cooled.

The heat pump 13 warms the breeding water by supplying the breeding water to the warming tank 9 when warming the breeding water, and cooling the breeding water by supplying the breeding water to the cooling tank 7 when cooling the breeding water.

As described above, the cooling tank 7 and the warming tank 9 can be selectively used as needed, so that the cold water cooled in the cooling tank 7 is supplied to the breeding water tank 11 through the third pipe L3 And the breeding water heated in the warming tank 9 can be discharged to the breeding water tank 11 through the fourth pipe L4.

Meanwhile, the skimmer 5 functions to remove organic matter from the carcass water discharged from the carcass water tank 11 and supply the organic matter to the carcass water tank 11 again.

Such a skimmer 5 generates bubbles in the breeding water, removes the bubbles after allowing the organic substances to adhere to the bubbles, and eventually removes the organic matter.

The skimmer 5 may be of various types such as a benture type, a needle wheel type, a mash wheel type, a wood stone type, and a becket type type.

The skimmer 5 of the Venturi type is a structure in which bubbles are produced by sucking air while passing breeding water through a Venturi 18 pipe at the inlet of the skimmer 5 by using a strong pressure pump 17.

The needle wheel system is a structure in which a plurality of needles are arranged on the impeller of the pump 17 so that the breeding water can pass the needle wheel through the Venturi 18 tube and break the bubbles more finely.

The mesh wheel system is a structure in which a plurality of mesh wheels are applied to the impeller of the pump 17 so that bubbles can be finely smoothed when the feed water passes through the mesh wheel.

Since the skimmer 5 having various structures can be used, the organic material can be removed by the skimmer 5.

The feed water from which the organic matter has been removed can be supplied to the breeding tank 11 through the fifth pipe L5 connected to one side.

Or is supplied to the cooling tank 7 or the warming tank 9 of the heat pump 13 before being supplied to the breeding water tank 11 and the temperature is adjusted and then fed through the third and fourth pipes L3 and L4, Or may be supplied to the water tub 11.

In the process described above, the breeding water is pumped from the breeding water tank 11 and returned to the breeding water tank 11 through the oxygen dissolver 3 and the heat pump 13, or returned through the skimmer 5 Breeding water was filtered.

However, the present invention is not limited to this, and groundwater can be used as a breeding water.

That is, the ground water is pumped by the pump 17 or the like to be used as breeding water, and the pumped breeding water may be supplied to the breeding water tank 11 after being heated or cooled by being supplied to the heat pump 13.

At this time, the process of supplying the ground water to the warming tank 9 or the cooling tank 7 of the heat pump 13 is the same as the process of supplying the breeding water, and thus a detailed description thereof will be omitted.

When groundwater is supplied to the warming tank 9 or the cooling tank 7 through the sixth pipe L6, it is necessary to prevent the groundwater from interfering with each other by being simultaneously supplied to the same tank as the breeding water.

Therefore, groundwater is supplied to the tank where the breeding water is not supplied. That is, when the feeding water is supplied to the cooling tank 7, the ground water is supplied to the warming tank 9, and when the feeding water is supplied to the warming tank 9, the ground water is supplied to the cooling tank 7.

Ground water heated in the cooling tank 7 or warmed in the warming tank 9 may be discharged to the breeding water tank 11.

The breeding water stored in the breeding water tank 11 is supplied to the oxygen dissolver 3 through the pump 17 and the venturi 18 and is then warmed or cooled through the heat pump 13, 11). ≪ / RTI >

The circulation filtration system described above is intensively disposed on one base B and includes a pump 17, a plurality of venturi 18, an oxygen dissolver 3, a heat pump 13, And the skimmer 5 may be disposed on one base B.

At this time, a plurality of Venturi (18) are disposed between the oxygen dissolver (3) and the skimmer (5) to efficiently use the space and selectively supply the breeding water, And the warming tanks 7 and 9 are disposed in the lower part of the base B so that the water for breeding is disposed on the path returning from the oxygen dissolver 3 to the breeding water tank 11, Cooled and then returned.

Claims (6)

A pump 17 for sucking the breeding water from the breeding water tank 11 by pumping;
A plurality of venturi (18) for mixing oxygen or air with the breeding water pumped by the pump (17);
An oxygen dissolver 3 for increasing the solubility of oxygen by feeding and storing oxygen in the venturi 18 through a first pipe L1;
A heat pump 13 that is cooled or warmed by feeding the breeding water discharged from the oxygen dissolver 3 through the second pipe L2; And
And a skimmer (5) disposed at a certain distance from the oxygen dissolver (3) and supplied with breeding water mixed with air in a venturi (18) disposed therebetween to remove organic matter by bubbles. . The method according to claim 1,
The Venturi 18 includes a venturi 18 disposed between the oxygen dissolver 3 and the skimmer 18 and connected to the oxygen dissolver 3 and a venturi 18 connected to the skimmer 5. [ ),
Characterized in that the venturi (18) is connected to an oxygen regulator (19) to control the amount of air sucked into the Venturi (18). The method according to claim 1,
The heat pump (13) includes an evaporator (E) for cooling the breeding water by heat exchange; A compressor (P) connected to the evaporator (E) to compress the refrigerant; A condenser (C) connected to the compressor (P) for warming the breeding water; And an expansion valve (V) connected to the condenser (C) to bring the refrigerant into a low pressure state,
The evaporator E is provided with a cooling tank 7 capable of storing and cooling the breeding water, a condenser C is provided with a warming tank 9 capable of storing warm water for warming,
The breeding water cooled in the cooling tank 7 can be discharged to the breeding water tank 11 through the third pipe and the breeding water warmed in the warming tank 9 is discharged to the breeding water tank 11 through the fourth pipe Wherein the circulating filtration system comprises: The method according to claim 1,
The skimmer (5) is connected to the Venturi (18) to feed the breeding water, and the other side is connected to the breeding water tank (11) by the fifth pipe so that the breeding water from which the organic matter is removed can be discharged. Filtration system. The method according to claim 1,
Wherein the groundwater is supplied to the heating tank (9) or the cooling tank (7) via the sixth pipe, and is supplied to a tank different from the tank in which the breeding water is supplied. The method according to claim 1,
A venturi 18 is disposed between the oxygen dissolver 3 and the skimmer 18 and between the oxygen dissolver 3 and the skimmer 18 at the upper portion of the base B and the lower portion of the base B The cooling water can be efficiently circulated through the oxygen dissolver 3 and the skimmer 18 and the cooling tank 7 and the warming tank 9 by arranging the cooling tank 7 and the warming tank 9, Wherein the use efficiency of the circulating filtration system is improved.

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