KR20150039061A - MNH Type Multi-Stage Aqua Firm - Google Patents

Abstract

The MNH type multistage culture plant according to the present invention includes a plurality of stacked type water tanks in which a plurality of cell water tanks having a length (L) longer than the width (W) are arranged in parallel and stacked at regular intervals in the height direction to produce flat fish; A water supply device for supplying water to the plurality of cell water tanks; A drainage device for draining water from the plurality of cell water tanks to maintain a constant water level; A plurality of air lifts are provided to rotate the water using the plurality of air lifts to purify the water supplied from the water drainage apparatus as microorganisms, Biofloat aquaculture tank that feeds non-flat fish species that require more than a certain depth of water in the aquaculture; The other end is connected to the water supply device to supply the sucked water to each cell tank of the plurality of stacked type water storage tanks, unit; And a water temperature regulating device for regulating the temperature of the water stored in the bioflare style water tank.

Description

MNH Type Multi-Stage Aqua Firm}

The present invention relates to a multi-stage farm where the yield per unit area can be increased.

In general, fish farming forms a farm in the sea or river, and the method of using seawater or freshwater is widely used. Thus, aquaculture in the sea or river has the advantage that the cost of the aquaculture facility is low and there is no need to separately exchange seawater or freshwater.

On the other hand, in recent years, technologies for the production of fish using seawater or freshwater have been developed in the inland far from the sea or river. In this way, when the fish are cultured in the sea using seawater or fresh water, the fish are cultured by adding seawater or fresh water to the tank. As such, inland fish farming and aquaculture have the advantage of not having geographical restrictions because they do not need to be adjacent to the sea or river.

However, when farms are constructed inland, the cost of land is higher than that of sea or river, making it difficult to construct farms on a large area. In addition, even if a farm is constructed with a large area, it is not easy to manage.

Taking this into account, research has been underway to build a building-type aquaculture as recently as the Korean Patent No. 10-1270107 (registered on May 27, 2013) and to increase the production per unit area compared to the existing aquaculture farm .

However, when the aquaculture type farm is constructed as in the above-mentioned prior art, it is necessary to maintain / operate separate facilities for treatment of excrement and purification of water, and it is essential to treat antibiotics and chemicals for removing foreign matter. Therefore, there is a problem that besides the additional cost due to the generation of wastewater, it is not good for the health of consumers who eat fish.

Korean Registered Patent No. 10-1270107 (registered on May 27, 2013)

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide an environmentally friendly multistage farm which can increase the production amount per unit area and maintain water quality and water temperature without adding chemicals.

The technical object of the present invention is not limited to the above-mentioned technical objects and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

A multi-tier aquarium according to the present invention includes: a plurality of stacked type water tanks in which a plurality of cell water tanks having a length (L) longer than a width (W) are arranged in parallel and stacked at regular intervals in height direction to produce flat fish; A water supply device for supplying water to the plurality of cell water tanks; A drainage device for draining water from the plurality of cell water tanks to maintain a constant water level; A plurality of air lifts are provided to rotate the water using the plurality of air lifts to purify the water supplied from the water drainage apparatus as microorganisms, Biofloat aquaculture tank that feeds non-flat fish species that require more than a certain depth of water in the aquaculture; The other end is connected to the water supply device to supply the sucked water to each cell tank of the plurality of stacked type water storage tanks, unit; And a water temperature regulating device for regulating the temperature of the water stored in the bioflare style water tank.

At least two or more cell water tanks having a width of 60 to 70 cm are arranged in parallel in the stacked style water tank, and a water level of the supplied water is 20 to 30 cm.

The water storage device may be installed at one end of the stacked type water storage tank so that a flow of water is formed in a longitudinal direction thereof, and a drainage device may be installed at the opposite end of the water supply device.

The drainage device includes a pipe-shaped body; And a drain slit formed through the side wall of the body, wherein a height of the drain slit is equal to a water level of the cell water tank.

The bioflavonable water tank includes a water tank body; A blocking wall disposed at the center of the water tub body and dividing the water tub body into a first zone and a second zone and having opposite ends spaced from the inner wall surface of the water tub body by a predetermined distance; A first air lift installed at one end of the first zone; And a second air lift installed at one end of the second zone, wherein the first and second air lifts are arranged so as not to face each other opposite to each other, and rotate the water contained in the first and second zones .

The water tub body may be formed of a concrete structure having a predetermined thickness or more.

The multi-stage farm site according to the present embodiment may further include an air supply device for additionally supplying air to the cell water tank.

Wherein the stacked style water tub comprises: a frame forming a skeleton; A plate member coupled to the frame; And a work path for work coupled to the frame.

Stacked aquariums of the same or similar shape can be piled up in layers to grow fish, which can increase the yield per unit area.

By circulating seawater used in aquaculture, the carbon dioxide and pollutants contained in the water are decomposed into microorganisms, and the air lift is used to constitute the purification tank so that oxygen-containing air can be dissolved in the water. It is not necessary to input and it is possible to implement a water tank environment suitable for healthy fish growth without adding chemicals for antibiotics or water filtration.

Because it can be installed in the inland, there is no worry of fish death due to natural disasters such as typhoons and red tides, and it is possible to fish in a narrow area.

It is possible to grow fish in the bottom of the aquaculture tank by flattening it with a water depth of only about 30cm, because the width is narrow and the length is long and forms a stacked aquarium. Therefore, It is possible.

In addition, when a stacked type water tank is formed by a narrow and long water channel, it is possible to maintain the quality of the aquaculture water at the highest level since there is hardly any square area where the inflow and outflow of water does not occur.

FIG. 1 is a perspective view schematically showing an example of a multi-stage farm in accordance with the present embodiment,
Fig. 2 is an enlarged view of the water level adjusting device as a main part of Fig. 1,
FIG. 3 is a side view schematically showing an example of a multi-stage farm in accordance with the present embodiment,
4 is a plan view schematically showing a cell water tank according to the present embodiment,
5 and 6 are a plan view schematically showing a bioflare-style water tank according to the present embodiment,
Figs. 7 and 8 are an exploded perspective view and a perspective view showing an example of an air lift installed in the bioflare-
Figs. 9 and 10 are sectional views showing an operating state of an air lift installed in the bioflare-style water tank of the first embodiment, Fig.
FIG. 11 is a sectional view showing the operating state of the air lift installed in the bioflare style water tank according to the second embodiment, and FIG.
12 and 13 are views showing a state in which a multi-tiered farm site according to the present embodiment is configured in a large scale.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. The definitions of these terms should be interpreted based on the contents of the present specification and meanings and concepts in accordance with the technical idea of the present invention. For reference, the MNH aquaculture is the name of the applicant's initials and means the inland aquaculture using Biofloc.

As shown in FIG. 1, the multi-tier farm according to the present embodiment includes a stacking type water tank 100, a water supply unit 200, a water drainage unit 300, a biofloat water tank 400, a pump unit 500, Adjustment device 600 may be included.

A plurality of cell water tanks 110, 120, and 130 having a length L longer than the width W are arranged in parallel. As shown in the figure, the three cell water tanks 110, 120, and 130 may be arranged in parallel, but the present invention is not limited thereto, and the number may be increased according to the area of the farm.

When a water stream is formed longer than the width, a flow of water is formed in a certain direction as in a water channel, thereby preventing contamination due to water stagnation. In addition, the water in the cell water tank 110, 120, It is possible to prevent the water from decaying. In addition, when the water channel is configured to have a width narrower than the length, it is possible to minimize the blind spot where the water stagnates when the water is circulated by the water flow formed by the introduced water and the discharged water.

On the other hand, in the stacked type water storage tank 100, the water supply device 200 may be installed at one end of the narrowly formed water supply device, and the drainage device 300 may be installed at the opposite end of the water supply device. This structure will be explained later.

The plurality of cell water tanks 110, 120, and 130 may have a width of 60 to 70 cm, and the water level of the supplied water may be maintained at 20 to 30 cm. It can be varied depending on the type of fish to be cultivated, and is preferably suitable for the production of fish with a flat shape such as a mineral.

The cell water tanks 110, 120, and 130 may have a width of 60 to 70 cm, which may be increased or decreased in accordance with the size of a cultured fish species. For example, when a foreign language is taken as an example, the length of the fully grown foreign matter can be increased up to 50 to 60 cm. Therefore, the width of the cell baths 110, 120, . Particularly, since flat fish such as a crab live on the bottom surface of a water tank, a deep water depth is not required, and even if a water level of about 20 to 30 cm is maintained, there is no problem in growth. By constructing the cell water tanks 110, 120, and 130 in the form of a channel having a length longer than the width, the amount of seawater used in a limited supply of seawater such as inland can be minimized. If the bulls are to be shipped at a height of 60 cm or more, the cell tanks 110, 120, and 130 may be wider as described above.

On the other hand, the stacked type water storage tanks 100 can be stacked and arranged at regular intervals in the height direction. At this time, the stacked type water storage tanks 100 to be stacked may be formed to have the same shape and size, or may be formed by increasing the size of the stacked type water storage tank 100 stacked above. It can be variously changed depending on the design.

The stacked type water storage tank 100 may be provided in at least two layers. If it is stacked excessively, it may not be easy to manage, and since it may consume a large amount of energy to pump the sea water upward, It is preferable to configure it not to exceed.

The stacked aquarium 100 may further include a frame 101, a plate member 102, and a work passage 103.

The frame (101) forms an outer periphery of the stacking type water storage tank (100) with an iron skeleton and can support a main load of the stacking type water storage tank (100). The frame 101 may be made of a steel frame having high strength, but it is not limited thereto, and synthetic resin having high strength such as FRP may be used as needed.

The plate member 102 is coupled with the frame 101 to form an internal space portion of the stacked type water storage tank 100. The plate member 102 is divided into the cell water tanks 110 and 120 by a space portion formed by the plate members 102, (130) may be formed.

The material of the plate member 102 may be variously formed, but it may be made of a synthetic material such as acrylic, PS, PP, PE, etc., which is light and robust, or may be formed of a material having high corrosion resistance such as tempered glass .

The work path 103 may be coupled with the frame 101 and may include a ladder 103a and a handrail 103b to which the operator may climb. In the work path 103, an operator can perform an operation for managing a stacked style water tank constituting a multi-stage farm site according to the present invention. That is, it is possible to check the water temperature, feed the food, and check the operation status of the air supply device.

The water supply device 200 supplies water to a plurality of cell tanks 110, 120 and 130, and the supplied water can be supplied through a bioflare-style water tank 400 to be described later. The water supply device 200 may include water supply ports 210, 220, and 230 installed for each of the plurality of cell tanks 110, 120, and 130. It is preferable that the installation positions of the water supply ports 210, 220 and 230 are formed at one end of the cell water tanks 110, 120 and 130. This is because the water spraying power supplied from the water supply ports 210, 220 and 230 and the water stored in the cell water tanks 110, 120 and 130 are discharged from the drainage device 300, 120, and 130, which are formed in the shape of a long channel in the longitudinal direction.

The drainage device 300 may be installed at the opposite end of the water supply ports 210, 220 and 230 as shown in FIGS. 3 and 4 for the above reason. The drainage device 300 is installed to maintain a constant water level in the cell tanks 110, 120, and 130. The drainage device 300 may include a drainage slit 320 formed through the side wall of the pipe-shaped body 310, as shown in FIG.

At this time, the clearance g of the drain slit 320 may be formed so as not to exceed 5 mm so that the fish in the form of a fish being formed into a fish or adult can not enter or suck into the inside of the body 310. Since the height of the drain slit 320 is determined to be the same as the water level of the cell water tanks 110, 120 and 130, it can be varied according to the required water level.

3, the drain slits 320 are disposed at both ends of the stacked type water storage tank 100 and the second stage II stacked type water storage tank, . Of course, although not shown, it is also possible to form the drainage device 300 so that the first and second stages (I) and (II) are formed to have the same size and then passed through them at the same time.

The bioflare aquarium 400 is installed below the stacked aquarium in the lowest layer of the plurality of stacked aquaria 100. According to the present embodiment, the bioflare-style water tank 400 may be a water channel type as shown in FIG. 5, or may be provided in a cylindrical shape as shown in FIG. Since the biofloat water tank 400 is formed to be able to drain water having a predetermined depth or more, it is possible to use a fish species that requires a certain depth and space in a style similar to that of a bucket, instead of a flat fish like the above- Can be used for cultivation. In addition, the bioflare-style water tank 400 also plays a role of producing the aquaculture water used in the stacking type water storage tank 100.

As shown in FIG. 5, the bioflare-style water tank 400 formed in a water channel shape rotates water by using a plurality of first and second air lifts 710 and 720. Water supplied from the drainage device 300, which is rotated and agitated by the first and second air lifts 710 and 720, can be purified by microorganisms. In this process, the microorganisms are removed from the ammonia The oxygen-containing air can be additionally supplied while decomposing the carbonic acid gas.

The water stored in the bioflavonable water tank 400 is water mixed with seawater and various microorganisms. At this time, microorganisms are formed not by adding additional enzymes or external additives but by growing microorganisms for 15 to 20 days in a natural state. At this time, if the water remains in the state of being in a state of being left as it is, the first and second air lifts 710 and 720 are operated to form a constant flow in the water to prevent the decay. When the bioflavonable water tank 400 is constructed as described above, microorganisms may be generated in the water by continuously circulating the water for a predetermined period of time without additional additives. These microorganisms have no effect on the survival of cultured fish. Especially, it is possible to decompose fish excrement and carbon dioxide naturally without introducing a separate antibiotic or cleaning agent into the water tank, and it is possible to produce an eco-friendly, fresh and healthy fish.

In the meantime, the channel type bioflav water tank 400 configured as described above includes a water tank body 410 and a blocking wall 420.

The water tank body 410 may be formed of a concrete structure having a predetermined thickness d or more. When the water tank body 410 is formed of a concrete structure, the external temperature change is not directly transferred to the water accommodated therein, thereby reducing energy required for water temperature maintenance. If necessary, the water tank body 410 may have a built-in heat insulating material.

The blocking wall 420 may be spaced a predetermined distance l from the inner wall surface of the water tank body 410 as shown in a plan view of the bioflare style water tank 400 shown in FIG. At this time, the separation distances at both ends can be the same. The blocking wall 420 may divide the bioflare-style water tank 400 in half and constitute a passage through which water can flow at a distance between the both ends. The water tub body 410 of the bioflawn style water tank 400 can be divided into the first zone A and the second zone B by the blocking wall 420. [

According to the present embodiment, a plurality of first and second air lifts 710 and 720 can be installed in the first and second zones A and B, respectively, at positions not facing each other. The structure of the first and second air lifts 710 and 720 may be the same. The first and second air lifts 710 and 720 can rotate the water contained in the first and second zones A and B, respectively. The structure of the first and second air lifts 710 and 720 can be variously configured according to the embodiments, which will be described later.

Meanwhile, as shown in FIG. 6, the bioflare-style water tank 400 may have a cylindrical shape.

The bioflare aquarium 400 may be provided with a funnel shape having a concave bottom surface, and aquaculture water may be contained therein. A first port 401 may be provided at the center of the bottom surface of the bioflare-style water tank 400, and a second port 402 may be provided at an upper surface of the side wall.

The Bioflare aquaculture water contained in the Bioflare aquarium 400 is rotated clockwise or counterclockwise by the super air lifter 750 so that foreign substances such as excretion contained in the aqua water can be decomposed by microorganisms . The super-air lift apparatus 750 may be provided with a flow rate adjusting device 751 for reducing the flow rate generated on the front surface thereof. The flow rate regulating device 751 prevents the aquaculture water stored in the bioflav water tank 400 from rotating too fast.

Meanwhile, foreign matter such as excretion produced by the fish cultured in the aquaculture water can be discharged to the outside through the first port 401 formed at the center of the bioflavoney tanks 400. At this time, The port 401 is provided with a grill member so as to prevent the fish being fed through the first port 401 from flowing into the circulation pipe. The grill member is not necessarily required and may be omitted, and the shape of the grill member may be variously configured. The grill member may have a plurality of through holes protruding upward from the first port 401, or may be configured to cover the inlet of the first port 401.

The first and second ports 401 and 402 may be connected to each other through a circulation pipe and an air lift device for circulation is installed in the circulation pipe. It is possible to discharge the air through the second port 402 to the bioflav water tank 400 by using the pressure while supplying air. The air lift apparatus for circulation is a cylindrical air lift apparatus according to the related art, and the air supply apparatus such as at least one air stone may be disposed inside the pipe.

One end of the pump unit 500 is immersed in the bioflare-style water tank 400 to suck the water inside the bioflawn-style water tank 400 to the suction port 510 and the other end thereof is connected to the water supply device And the sucked water is supplied to each of the cell tanks of the plurality of stacked type water tanks.

The water temperature controller 600 senses the temperature of the water contained in the stacked type water tank 100 and the bioflawn type water tank 400 and detects the temperature of the water stored in the stacked type water tank 100 and the fish Adjust the water temperature to the appropriate water temperature. The water temperature regulating device 600 may be configured in various ways. For example, the hot water pipe connected to the boiler may be immersed in the bioflav water storage tank 400 to adjust the water temperature of the aquaculture water. The bioflav water storage tank 400 may be constructed of a double water tank, It is also possible to control the temperature of the aquaculture water while exchanging heat through the bottom and sidewall surfaces. In this case, the water temperature of the aquaculture water can be controlled by entering and exiting the cooling water for heat exchange higher or lower than the aquaculture water in the double water tank.

The air supply device 650 may be installed in each of the cell water tanks 110, 120, and 130 of the stacked type water storage tank 100, as shown in FIGS. According to this embodiment, a pipe 650a is provided on the upper side of the plate 102 for partitioning each of the cell tanks 110, 120 and 130, and oxygen is contained in the water flowing from the pipe 650a And a discharge portion 651 connected to an air stone for supplying air.

The first and second air lifts 710 and 720 are installed inside the bioflare-style water tank 400 to form a water flow in the bioflare-style water tank 400. Since the first and second air lifts 710 and 720 may have the same structure, the first air lift 710 will be described below.

FIG. 7 is an exploded perspective view of the first air lift 710 according to the first embodiment, FIG. 8 is an assembled perspective view of FIG. 7, and FIG. 9 is a sectional view taken along line II 'of FIG.

The first air lift 710 includes an air lift body 71 1 and a slide member 712, as shown in Figs. The air lift body 711 may further include an air supply unit 730 and an air supply pipe 740.

The air lift body 711 includes a first body 711a and a second body 711b.

The first body 711a is formed in a hollow pipe shape having a first diameter D1. The first body 711a may be formed of a synthetic resin material such as PVC. A plurality of through holes 711c are formed in the lower end of the first body 711a. The through holes 711c may be formed through the first body 711a or concave from the lower end of the first body 711a.

  The plurality of through holes 711c formed at the lower end of the first body 711a allow water outside the first body 711a to flow into the first body 711a through the through holes 711c, 711a to the second body 711b to be described later.

In the first embodiment of the present invention, the first body 711a having a first diameter is a portion in which an air supplier 730 to be described later is disposed. The first diameter is larger than the size of the air supplier 730, Thereby preventing fish from being caught between the feeder 730 and the first body 711a.

The second body 711b is connected to the first body 711a. The second body 711b has a second diameter D2 that is smaller than the first diameter D1 of the first body 711a and the second body 711b has a hollow pipe shape.

On the outer surface of the second body 711b, a first opening 711d formed in the axial direction (longitudinal direction) of the second body 711b is formed.

The first opening 711d of the second body 711b is formed into a slit shape elongated toward the axial direction of the second body 711b and is inserted into the first body 711a and the second body 711b through the first opening 711d. And the water introduced through the body 711b is discharged.

At the upper end of the second body 711b, a pair of coupling grooves 711e formed to face each other is formed. The coupling grooves 711e are recessed from the upper end of the second body 711b in a concave shape and a fixing member (not shown) having a pipe shape for fixing the air lift 710 is coupled to the coupling groove 711e .

In the first embodiment, the second body 711b is formed as one member, but not limited thereto, and the second body 711b may be formed of two or more members fitted to each other. When the second bodies 711b are composed of two members fitted to each other, the overall length of the second bodies 711b may be increased or decreased corresponding to the height of the water surface.

The slide body 712 is engaged with the outer surface of the second body 711b of the air lift body 711. [ The slide body 712 may be formed in a semicylindrical shape but is not limited thereto and may be provided in a cylindrical shape as required. The slide body 712 is configured to have a diameter slightly larger than the outer circumferential surface of the second body 711b so as to be lifted or lowered along the outer surface of the second body 711b, You can move up and down along the side.

The slide body 712 can be raised or lowered along the outer surface of the second body 711b by the buoyancy of the slide body 712 according to the water level, can do. Alternatively, although not shown, it is also possible to add a buoyancy device (not shown) such as an air tube to the slide body 712 to give sufficient buoyancy. The length of the slide body 712 may correspond to the length of the first opening 711d. The slide body 712 is disposed at a position covering the slit-shaped first opening 711d formed on the outer surface of the second body 711b of the air lift body 711. [

The slide body 712 is formed with a second opening 712a communicating with the first opening 711d and the first opening 711d and the second opening 712a are disposed to face each other. The second opening 712a may be formed in a rectangular shape when viewed from the front. The second opening 712 is formed in a cylindrical shape having a rectangular parallelepiped shape with open ends at both ends, and the discharge port 712b has an expanded shape toward the outside.

The water discharged from the discharge port 712b is discharged in a direction parallel to the water surface so that the water discharged from the discharge port 712b and the air bubbles contained in the discharged water can be further injected from the air lift 710. [ Accordingly, the water jetted through the discharge port 712b can form a rotating water flow in the bioflare-style water tank 400.

An air supply unit 730 and an air supply pipe 740 are disposed inside the air lift body 711. The air supply unit 730 and the air supply pipe 740 are connected to each other by air bubbles in the air lift body 711 The air bubbles are raised along the first body 711a and the second body 711b of the air lift body 711 so that water flows from the first body 711a toward the second body 711b .

The air supplier 730 may be provided as an air stone and communicates with the air supply pipe 740 to generate a plurality of air bubbles. The air supply pipe 740 provides the air outside the air lift body 711 to the air supplier 730. Since the air supplier 730 and the air supply pipe 740 are commonly used in the known technology, detailed description thereof will be omitted.

9 and 10 are sectional views showing the operation of the air lift apparatus according to the water level.

9, the slide body 712 is raised or lowered along the second body 711b of the air lift body 711 by its own buoyancy in response to the water level, And the discharge body 220 coupled to the slide body 712 are adjusted in parallel with the water level. Of course, it is also possible for a worker to adjust the position of the slide body 712 to be formed at a suitable position.

Subsequently, when air is supplied to the air supplier 730 through the air supply pipe 740, a large number of air bubbles are generated from the air supplier 730, and air bubbles are generated from the first body 711a to the second body 711b Raise toward the top.

As the air bubbles rise from the first body 711a toward the upper end of the second body 711b, the water W in the first and second bodies 711a and 711b also rises together with air bubbles .

The raised water and air bubbles in the first and second bodies 711a and 711b are connected to the first opening 711d of the second body 711b and the second opening 712a of the slide body 712 And is discharged in a direction parallel to the water surface through the discharge port 712b.

Referring to FIG. 10, when the water level is lowered by natural evaporation, drainage, or the like, as shown in FIG. 9, the operator lowers the slide body 712 in response to the water level. The raised water and air bubbles in the first and second bodies 711a and 711b are then separated from the first opening 711d of the second body 711b and the second opening 712a of the slide body 712, In the direction parallel to the water surface.

By thus raising or lowering the slide body 712 in accordance with the water level, water mixed with air bubbles can be discharged irrespective of the water level to prevent fish loses and the like. In order to discharge water mixed with air bubbles, It is not necessary to provide a large amount of water to adjust the water level, which can greatly reduce the production cost.

The air lift 710 having the discharge port 712b slidable in this way can be very useful when culturing fish inhabited by sea using inland water remote from the sea.

11 is a view showing an air lift 1710 according to the second embodiment.

The air lift 1710 according to the second embodiment may include a pipe-shaped body 1710 and an outlet pipe 1720 protruding from one side wall of the body 1710. At this time, the same air supplier 730 and the air supply pipe 740 as those of the first embodiment may be disposed inside the body 1710. The air supply 730 and the air supply pipe 740 generate air bubbles inside the air lift body 1710 so that water can be discharged from the body 1710 to the discharge pipe 1720.

Figs. 12 and 13 are views showing a case where a multistage farm constructed in the above-described concept is constructed on a large scale.

As shown in the figure, the bioflare-style water tank 400 circulates and supplies the aquaculture water to the multi-stage aquaculture site of the first group (I) in which the multiple aquaculture type aquaculture water tanks 100 are stacked. At this time, the aquaculture water can be circulated and supplied to the second group (II) and third group (III) multi-stage farms having the same structure in the same manner. At this time, the water supply and drainage apparatuses 200 and 300 of the water tank type stacking type water tanks 100 in which the water flow is formed in a predetermined direction by supplying and discharging water in common can be commonly arranged. At this time, the biofloat-style water tank may be formed at a certain depth in the ground, as shown in FIG. 3, and the drain pipe of the drainage device 300 may be buried in the ground.

The configuration of the air lift according to the first and second embodiments is illustrative and may be provided in various configurations as required. The air lift can be used in any configuration capable of forming water flow while supplying air to the water.

According to the present invention as described above, oxygen contained in the air can be supplied to the aquaculture water using the air lift 1710 and used as a power source for generating rotational power of the aquaculture water. Therefore, the water in the bioflo spring-type water tank 400 does not decay. Therefore, the water can be supplied to the stacking type water storage tanks 100 and used again. Therefore, it is possible to construct the farms by stacking the stacking type water storage tanks 100 in a relatively narrow urban or inland area, Can increase.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

100; A stacked aquarium 101; frame
102; Plate member 103; Work path
110; A first cell water tank 120; The second cell water tank
130; A third cell water tank 200; Water supply device
300; Drainage device 400; Bioflavon water tank
500; A pump unit 600; Water temperature controller
710; A first air lift 720; The second air lift
730; Super Air Lift Device

Claims (9)

A plurality of stacked type water tanks in which a plurality of cell water tanks having a length (L) longer than a width (W) are arranged in parallel and stacked at regular intervals in height direction to produce flat fish;
A water supply device for supplying water to the plurality of cell water tanks;
A drainage device for draining water from the plurality of cell water tanks to maintain a constant water level;
And a plurality of air lifts are used to rotate the water to purify the water supplied from the water drainage device by the microorganisms, A biofloat aquaculture tank that cultivates non-flat fish species that require water depths above a certain depth;
The other end is connected to the water supply device to supply the sucked water to each cell tank of the plurality of stacked type water storage tanks, unit; And
And a water temperature regulating device for regulating the temperature of the water stored in the bioflare-style water tank.
2. The multi-layered aquarium according to claim 1,
At least two cell tanks having a width of 60 to 70 cm are arranged in parallel and the water level of the supplied water is 20 to 30 cm.
2. The multi-layered aquarium according to claim 1,
MNH-type multi-stage farm where the water supply device is installed at one end portion formed narrowly so as to form a flow of water in the longitudinal direction, and a drainage device is installed at the opposite end.
The water treatment system according to claim 1,
A pipe-shaped body; And
And a drain slit formed through the side wall of the body,
And the height of the drain slit is formed to be equal to the water level of the cell water tank.
The bioflavouring type water tank according to claim 1,
A water tank body;
A blocking wall disposed at the center of the water tub body and dividing the water tub body into a first zone and a second zone and having opposite ends spaced from the inner wall surface of the water tub body by a predetermined distance;
A first air lift installed at one end of the first zone; And
And a second air lift installed at one end of the second zone,
Wherein the first and second air lifts are arranged so as not to face each other opposite to each other so as to rotate water contained in the first and second zones.
6. The watercraft according to claim 5,
MNH-style multi-stage aquaculture plant with a concrete structure with a certain thickness or more.
The method according to claim 1,
And an air supply device for additionally supplying air to the cell water tank.
2. The multi-layered aquarium according to claim 1,
A frame forming a skeleton;
A plate member coupled to the frame; And
And a work passageway for working coupled to the frame.
9. The method according to any one of claims 1 to 8,
The MNH type multi-stage farm where a plurality of stacked style water tanks are stacked in a layered manner and a group of stacked style water tanks are arranged in a row and a row in parallel to supply water of the biofloat style water tank.

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