KR102065451B1 - High density Aquaculture System - Google Patents

Abstract

The present invention relates to an environmentally friendly high density aquaculture system.
Eco-friendly high-density aquaculture system of the present invention, the bio-floc tank 100 is installed heat exchanger 110 therein; A plurality of underground heat exchangers 210 installed in the ground and one side thereof are connected to pipes, and the other side thereof is connected to the heat exchanger 110 to heat the inside of the water tank; It is configured to include; oxygen supply device 300 for supplying oxygen to the bio-floc tank (100).
According to the present invention, by using geothermal heat without using a separate boiler to increase the temperature of the water inside the biofloc tank, eco-friendly high density farming is possible. Without installing the required circulation pump or oxygen supply device, a guide member having one side concave shape is installed to be inclined at an acute angle with respect to the bottom surface of the tank, and a bubble generating means is installed below the guide member to generate bubbles from the bubble generating means. Is to be inclined to rise along the concave passage of the guide member, by forming a plurality of holes on the surface of the guide member so that the small bubbles generated in the bubble generating means to rise slowly while moving out of the guide member through the hole, the large size Bubbles move along the guide member, causing fluid in the tank By promoting the circulation, it is possible to circulate the fluid in the tank without a separate circulation pump, to supply a large amount of oxygen in the tank, and to install the auxiliary guide member on the upper part of the guide member to guide the movement and diffusion of small bubbles. It is possible to, and the guide member is made easier to diffuse the small bubbles by making the upper and lower portions of the hole to form a discontinuous inclined surface.

Description

Eco-friendly high density aquaculture system {High density Aquaculture System}

TECHNICAL FIELD The present invention relates to aquaculture systems, and to environmentally friendly high density aquaculture systems that operate with minimal external energy sources utilizing geothermal heat as a heat source while using a bio-floc technology (BFT) method that does not require water exchange.

Bio-floc technology (BFT), or bio-floc, refers to a state in which microorganisms multiply and grow like fuzz, and changes in growth are usually produced by using bio-floc instead of judging algae. This is called BFT.

These BFTs have the advantage of naturally and artificially producing bio-flocs in a pond or tank, which is more stable and can be maintained unchanged than algae-dependent farming.

When bacteria multiply and accumulate, they become like tiny downy hairs, which are called flocs.

The floc is 10 to 100 times faster than algae, which breaks down large amounts of shrimp manure and untreated feed-based nitrogenous wastes, which not only act day and night, but are also unaffected by weather, In addition, shrimp are also high in protein.

Recently, the bio-floc is used to apply not only to shrimp but also to loach such as loach.

However, such bio-floc aquaculture methods typically require a filtration facility to prevent the introduction of disease agents.

In addition, the water temperature of the water to be maintained to 30 ° C or more, conventionally there was a problem that a lot of facilities and costs are required for the water heating equipment when the country is not a relatively high temperature, such as subtropical climate.

In addition, since it is a farming method that does not use water other than water, there is a difficulty in managing water because the circulation and detonation of the water inside the tank should be made smoothly.

As described above, the technology related to the oxygen supply and circulation in the water tank includes an underwater air bubble guide device (Korean Patent Publication No. 10-0840623, Patent Document 1) in which a plate is arranged in a zigzag form on top of the bubble generator in a bubble generator. A technique is disclosed in which bubbles generated are zigzag guided by a plate so that they can be floated as slowly as possible to supply sufficient oxygen to the water in the tank.

However, Patent Document 1 has a problem in that a plate installed for inducing bubbles restricts movement of fish and the like in a tank, and requires a facility and a process for cleaning algae or moss by the installed plate. .

As a technique to solve this problem, "multifunctional sintered material micro-bubble generating device for filter bottles with a bubble diffusion induction plate" (Korean Patent Publication No. 20-2010-0009141, Patent Document 2) is hard to the edge of the bubble generating device The photo guide plate was provided to induce diffusion of bubbles generated through the inclined guide plate.

Patent document 2 has the advantage that the bubbles are evenly diffused in the tank by the induction plate installed in a multi-layer by the radiation acid, but it does not inhibit the movement of the bubbles rapidly rising to the top of the tank, so that the water in the tank is supplied with sufficient oxygen There was a problem that can not.

On the other hand, in the "bubble supply microbubble supply device and microbubble supply method" (Korean Patent Publication No. 10-1009690, Patent Document 3) in the case of the microbubble small particles are larger than the larger particles, the time remaining in water The technique of supplying microbubbles in a water tank using the fact that it can lengthen and increase the amount of dissolved oxygen may be disclosed.

In the case of Patent Document 3, but it is helpful to increase the amount of dissolved oxygen, such micro-bubbles should also be supplied evenly diffused in the tank, there was a problem that must be provided with a separate circulation device.

KR 10-0840623 (2008.06.17) KR 20-2010-0009141 (2010.09.17) KR 10-1009690 (2011.01.13)

Environment-friendly high-density aquaculture system of the present invention is to solve the problems occurring in the prior art as described above, to increase the water temperature inside the biofloc tank to enable eco-friendly high-density aquaculture by using geothermal heat without a separate boiler will be.

In addition, a guide member having a concave shape on one side is inclined at an acute angle with respect to the bottom of the tank without installing a circulation pump or oxygen supply device that requires separate power to circulate water and supply oxygen in the tank. In the lower part of the guide member, a bubble generating means is installed so that the bubble generated by the bubble generating means rises obliquely along the concave passage of the guide member, and a plurality of holes are formed on the surface of the guide member to form a small bubble generated by the bubble generating means. Is to slowly rise while moving out of the guide member through the hole, the large bubbles to move along the guide member to promote the circulation of the fluid in the tank to circulate the fluid in the tank without a separate circulation pump, To supply oxygen.

At this time, by installing the auxiliary guide member on the upper guide member to guide the movement and diffusion of small bubbles more.

In addition, the guide member is intended to facilitate the diffusion of small bubbles by making the upper and lower portions of the hole to form a discontinuous inclined surface.

Eco-friendly high-density aquaculture system of the present invention, in order to solve the above problems, the bio-floc tank 100 is provided with a heat exchanger 110 therein; A plurality of underground heat exchangers 210 installed in the ground and one side thereof are connected to pipes, and the other side thereof is connected to the heat exchanger 110 to heat the inside of the water tank; It is configured to include; oxygen supply device 300 for supplying oxygen to the bio-floc tank (100).

At this time, the oxygen supply device is installed to be inclined at an acute angle with respect to the bottom surface of the water tank 100, the cross section of the guide to form a sloped passage 11 taking the concave shape of the bottom portion toward the bottom of the water tank 100. Member 10; It is provided on the bottom side of the lower side of the guide member 10, the bubble generating means 20 for generating bubbles; comprising, a plurality of holes 12 are formed along the longitudinal direction of the guide member 10 It is characterized by that.

In addition, the bottom surface of the water tank 100 is installed to be inclined at an acute angle, and the shape of the cross section has a concave shape of the bottom portion facing the bottom of the water tank 100, and is spaced apart from the top surface of the guide member 10. Auxiliary guide member 50 for forming an auxiliary passage 51 inclined between the upper surface portion of the member 10; characterized in that it is further provided.

In addition, the guide member 10 is characterized in that the upper portion 13 and the lower portion 14 of the hole 12 forms a discontinuous inclined surface.

In addition, a plurality of auxiliary holes 52 are formed along the longitudinal direction of the auxiliary guide member 50.

According to the present invention, eco-friendly high-density farming is possible by utilizing geothermal heat without providing a separate boiler to increase the water temperature in the biofloc tank.

In addition, a guide member having a concave shape on one side is inclined at an acute angle with respect to the bottom of the tank without installing a circulation pump or oxygen supply device that requires separate power to circulate water and supply oxygen in the tank. In the lower part of the guide member, a bubble generating means is installed so that the bubble generated by the bubble generating means rises obliquely along the concave passage of the guide member, and a plurality of holes are formed on the surface of the guide member to form a small bubble generated by the bubble generating means. Is to slowly rise while moving out of the guide member through the hole, the large bubbles to move along the guide member to promote the circulation of the fluid in the tank to circulate the fluid in the tank without a separate circulation pump, Oxygen can be supplied.

At this time, by installing the auxiliary guide member on the upper guide member it is possible to more guide the movement and diffusion of small bubbles.

In addition, the guide member is made easier to diffuse the small bubbles by making the upper and lower portions of the hole to form a discontinuous inclined surface.

1 is a conceptual diagram showing an embodiment of an environment-friendly high density aquaculture system according to the present invention.
Figure 2 is a conceptual diagram showing another embodiment of the environment-friendly high density aquaculture system according to the present invention.
Figure 3 is a perspective view showing an embodiment of the oxygen supply device in the present invention.
4 is a schematic diagram showing an operating state according to the embodiment of FIG.
5 is a schematic view showing an example in which the auxiliary guide member is additionally installed.
6 is a perspective view and a schematic view showing an embodiment in which the upper and lower holes of the guide member form a discontinuous inclined surface.
7 is a schematic view showing an example in which an auxiliary hole is formed in the auxiliary guide member.

Hereinafter, the environment-friendly high density aquaculture system of the present invention will be described in detail with reference to the accompanying drawings.

Eco-friendly high-density aquaculture system of the present invention comprises a bio-floc water tank 100, heat pump 200, oxygen supply device 300.

The biofloc tank 100 is configured such that water is stored inside, such as a tank used in a known biofloc farm, and a cover such as a plastic house is installed at the top.

The installation of a cover such as a plastic house is to prevent viral disease infection and to minimize the influence of the external environment.

The biofloc tank 100 has a heat exchanger 110 installed therein as shown in the drawing, and the heat exchanger 110 has one side connected to a heat pump 200 and a pipe through which heat medium is introduced and discharged. The side is formed with an inlet, outlet through which water in and out of the water tank 100 is introduced.

The heat exchanger 110 is a well-known configuration, detailed illustration and description will be omitted.

The heat pump 200 is connected to a plurality of underground heat exchangers 210 installed in the ground and one side is connected to the pipe, the other side is connected to the heat exchanger 110 is configured to heat the inside of the tank.

Geothermal heat pump 200 is disclosed in a number of Patent Publication No. 10-1199020.

In general, the underground heat exchanger 210 for underground heat absorption is buried underground, and the thermal heat exchanger 210 stores heat medium for moving the heat after heat exchange in the ground.

The heat pipe may be used as the ground heat exchanger 210, but is not limited thereto.

In addition, the underground heat exchanger 210 is connected to the heat pump 200 by a pipe, the heat pump 200 is connected to an expansion valve, a compression, a condenser, a four-way valve and the like like a known heat pump.

The oxygen supply device 300 is configured to supply oxygen into the biofloc water tank 100, and various known aeration devices or bubble generators may be installed.

In the accompanying drawings, there is shown a configuration for supplying external air by a blower, but is not limited thereto.

In this case, as shown in FIG. 2, a filtration pump 410 is provided to which water is supplied in the water tank 100, and the water sucked from the filtration pump 410 is filtered through a filtration drum or the like installed therein. By installing a filter 400 to supply to the water tank 100 may be configured to maintain a constant water quality in the water tank (100).

The configuration as described above is a BFT in a region where the climate change is severe or generally low temperature by using geothermal heat as a heat source to increase the temperature inside the tank (100) when high-density farming shrimp, etc., such as external power or oil The use of energy sources can be minimized, resulting in economical high density farming.

However, in such a bio-floc culture, it is important to supply sufficient oxygen in the tank and circulate the water.

To this end, a blower is installed as an oxygen supply device for supplying oxygen into the tank as shown in the drawing, and a circulation pump for circulation of water in the tank is required. This, in turn, adds to the economic burden on the user, given the recent rise in power usage.

In this configuration, the oxygen supply device includes a guide member 10 and bubble generating means 20 which will be described later, while supplying sufficient oxygen to the water and smoothly circulating the water while minimizing the use of electric power. It can be minimized.

Specifically, the oxygen supply device,

A guide member 10 which is installed to be inclined at an acute angle with respect to the bottom surface of the water tank 100, and has a concave shape of the bottom portion facing the bottom of the water tank 100 to form an inclined passage 11;

It is provided on the bottom surface side lower portion of the guide member 10, the bubble generating means 20 for generating bubbles;

A plurality of holes 12 are formed along the longitudinal direction of the guide member 10.

The guide member 10 is installed to be inclined at an acute angle with respect to the bottom surface of the water tank 100, as shown in Figure 3, the cross-sectional shape is inclined in the shape of the bottom portion toward the bottom of the water tank 100 inclined passage (11) It is configured to achieve

In addition, the bubble generating means 20 is installed in the lower side of the bottom side of the guide member 10 is made to generate bubbles.

The bubble generating means 20 may be made of a known air bubble generating device known to form a large number of microbubbles or air stones generally used in the water tank 100.

In this configuration, as shown in FIG. 3, a plurality of holes 12 are formed along the longitudinal direction of the guide member 10.

The operation state according to this is shown in FIG. 4, as shown in the drawing, bubbles generated by the bubble generating means 20 such as an air stone or a microbubble generating device tend to rise vertically due to a specific gravity difference. The movement is moved along the passage 11 of the guide member 10 by the inclined guide member 10 while taking the shape.

However, the guide member 10 is provided with a plurality of holes 12, and the bubbles 30 larger than the size of the hole 12 are moved along the passage 11 of the guide member 10, and the size of the holes 12 is perforated. The small bubble 40 rises through the hole 12.

At this time, since the large bubble 30 has a large lifting force, when a large circulation force is generated when viewed in the entire tank 100, as shown in FIG. 3, the entire tank 100 is annularly installed in the tank 100. ) The circulation of water in the water will occur.

This plays a role of generating circulation of water in the water tank 100 without installing a separate circulation pump.

On the other hand, since the bubbles passing through the hole 12 formed in the guide member 10 are small in size, they are slower than the bubbles 30 having a large rising speed in the water, so that the water in the water tank 100 contacts the bubbles. The time to increase the bar, it serves to increase the amount of dissolved oxygen of the water in the tank (100).

As described above, the hole 12 formed in the guide member 10 separates the bubbles generated by the bubble generating means 20 according to the size, so that the small bubbles 40 are rapidly raised together by the large bubbles 30. To prevent the small bubbles 40 from being separated from the large bubbles 30 and gradually rising while remaining in the water at a slow speed, thereby increasing the dissolved oxygen of the water in the water tank 100 as well as the circulation of the water in the water tank 100. It will play a role.

The size of the hole 12 for this purpose may be formed differently depending on the size of the bubble generated by the bubble generating means (20).

For example, in the case of a general air stone, a hole 12 of several mm units may be formed, and in the case of a device that forms a smaller bubble 40 such as a microbubble generating device, the hole 12 may be smaller in size. can do.

On the other hand, in the configuration as described above, through the hole 12 of the guide member 10 to guide the movement direction of the small bubbles 40 separated from the large bubble 30 to the circulation of water in the overall water tank 100 It can be utilized.

To this end, as shown in Figure 5 is installed to be inclined at an acute angle on the bottom surface of the water tank 100, the cross-sectional shape of the bottom portion toward the bottom of the water tank 100 takes a concave shape, the guide member 10 It may be further provided with an auxiliary guide portion spaced apart from the upper surface portion of the) to form an auxiliary passage 51 inclined between the upper surface portion of the guide member 10.

At this time, the auxiliary guide member 50 may be formed with a plurality of auxiliary holes 52 along the longitudinal direction of the auxiliary guide member 50, as shown in FIG.

The auxiliary hole 52 may be formed to have the same diameter as the hole 12 formed in the guide member 10, but may be formed smaller than this to further separate the bubbles generated by the bubble generating means 20 in detail. The amount of oxygen may be increased, and the flow of water in the water tank 100 may be smoother.

In the above configuration, if the passage 11 in the guide member 10 is in a straight line, even if the hole 12 is perforated, the larger air bubble 30 is formed along the straight passage 11 in the straight line. Small bubbles 40 may also move along the passage 11.

As illustrated in FIG. 6, the guide member 10 has an upper portion 13 of the hole 12 as a method for solving such a problem to make the separation of the large bubble 30 and the small bubble 40 more smooth. And the lower portion 14 may form a discontinuous surface inclined surface.

This may be applied to the shape of the auxiliary guide member 50 as shown in FIG.

This configuration is because the small bubbles 40 rising along the wall of the guide member 10 due to the step 13 in the upper portion 13 and the lower portion 14 of the hole 12 skips the hole 12, the passage 11 It does not rise to the inside, and it floats at low speed underwater through the hole 12 as it is by a step | step.

When the oxygen supply device 300 is provided as described above, it is possible to use external power with the heat pump 200 connected to the underground heat exchanger 210 at a minimum, so that the bio-saturation season is severe even in Korea or the north. High density farming with flocs is possible.

In particular, the heat pump may be used for cooling, not heating, depending on the operation method, and many of these methods have been disclosed. In the event of excessive rise in summer temperature, the temperature is also lowered, causing problems such as mass death due to high temperatures. You will be able to solve it.

Eco-friendly high-density aquaculture system according to the present invention is suitable for high-density aquaculture, such as shrimp or loach, but is not limited thereto, and may be used for aquaculture, such as zooplankton.

1: water tank 10: guide member
11: passage 12: hall
13: upper 14: lower
20: bubble generation means 30: large bubbles
40: small bubble 50: auxiliary guide member
51: auxiliary passage 52: auxiliary hole
100: tank 110: heat exchanger
210: underground heat exchanger 200: heat pump
300: oxygen supply unit 400: filter
410: filtration pump

Claims (5)

In aquaculture systems,
A biofloc tank 100 having a heat exchanger 110 installed therein;
A heat pump (200) connected to the ground heat exchanger (210) installed in the ground and the other side thereof connected to the heat exchanger (110) to heat the inside of the water tank;
Consists of, including; oxygen supply device 300 for supplying oxygen into the bio-floc tank 100,

The oxygen supply device,
A plurality of annularly installed in the water tank 100, is inclined so as to be an acute angle with respect to the bottom surface of the water tank 100, the cross-sectional shape is inclined to take the concave shape of the bottom portion toward the bottom of the water tank 100 (11) Guide member 10 forming a);
It is provided on the bottom surface side lower portion of the guide member 10, the bubble generating means 20 for generating bubbles; comprising;
A plurality of holes 12 are formed along the longitudinal direction of the guide member 10,

The bottom surface of the water tank 100 is installed to be inclined at an acute angle, and the shape of the cross section has a concave bottom portion facing the bottom of the water tank 100, and is spaced apart from the upper surface of the guide member 10 to guide members ( Auxiliary guide member 50 for forming an auxiliary passage 51 inclined between the upper surface portion of 10) is further provided,

The guide member 10 is the upper portion 13 and the lower portion 14 of the hole 12 forms a discontinuous inclined surface,

A plurality of auxiliary holes 52 are formed along the longitudinal direction of the auxiliary guide member 50,

The auxiliary hole 52 is made smaller in diameter than the hole 12,

The auxiliary guide member 50 is characterized in that the upper and lower portions of the auxiliary hole 52 forms a discontinuous inclined surface,

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