KR102106202B1 - A biological low-water-exchanging recirculating aquaculture system by swirling-skimmer filtering method - Google Patents

Abstract

The present invention relates to a system and method for circulating low-return water using microorganisms, supplying aquaculture water containing foreign substances at a predetermined flow rate to create a vortex, and slowing the vortex to settle sedimented foreign substances to primaryly aquaculture water. A vortex filter to filter, and a skimmer filter to filter secondly by receiving the first filtered water from the vortex filter, and a secondly filtered cultured water from the skimmer filter to decompose foreign substances by using the biological action of microorganisms And a bio-filter to remove, and a grid-type water tank composed of a plurality of water tanks separated by a lattice to facilitate removal of organic matter at the bottom while being supplied with aquaculture water from which the foreign matter has been decomposed and removed by microorganisms. Sequential water vortex filter, skimmer filter, bio filter, sequential tank As may be operated in a low-exchange cycle system to supplement the lack of delivery due to evaporation in a water bath, and organic matter discharged while circulating.

Description

A biological low-water-exchanging recirculating aquaculture system by swirling-skimmer filtering method}

The present invention relates to a low-return circulation aquaculture system and method using microorganisms, and more specifically, a swirling-skimmer filtering method that minimizes clogging of a filtering device, and easy removal of organic matter from the bottom of aquaculture breeding tanks. Recirculating aquaculture system (RAS) circulating aquaculture system and method for aquaculture consisting of one lattice tank.

The aquaculture industry is largely divided into the aquaculture industry, which artificially breeds sea creatures in the sea, and the inland aquaculture industry, which breeds fish near rivers and lakes. As it is used, the strong solution problem of aquaculture industry is to remove it because strong viscous feed residues, feces, and bio-flocks generated in aquaculture tanks are widely accumulated on the entire floor to produce toxic substances in water such as ammonia and nitrite. to be.

In aquaculture tanks, toxic substances such as ammonia are generated in the process of decomposition of organic matter such as fish waste and remaining food by heterotrophic bacteria, and these ammonia is converted into nitrite (NO2) by metabolism when aerobic bacteria Nitrosomonas bacteria are present, and nitrite is Nitrobacter bacteria convert nitrate (NO3) into a series of nitrogen cycles. Even though ammonia in water is in the form of ammonium (NH3 / NH4), it is a major cause of fish death by harming fish with nitrite. In aquaculture plants without aquatic plants, an increase in nitrate levels is detrimental to fish, and eventually water or purification is needed to lower the nitrate levels generated by organic matter through partial return.

In this way, the removal of organic matter on the floor, which is important in aquaculture farms, increases the amount of return to water with frequent changes, and the difficulty of cleaning work due to the use of high-pressure cleaning equipment, stress of farmed fish that are frequently contacted with workers, and the possibility of disease transmission. Had.

In addition, there is a constant risk of increased costs due to repeated heating / cooling operations due to an increase in the amount of return, and the introduction of parasites, red tides, viruses, and disease sources when entering seawater.

For this reason, as an aquaculture facility embodying aquaculture type, there has been known a technique of intensive high-density production of fish by a recirculation aquaculture system (RAS). The circulating aquaculture system can be divided into a water intake device or an artificial seawater manufacturing facility, an oxygen supply device, a sedimentation and filtration and a discharge water treatment device, centering on aquaculture tanks.

The water intake device is implemented to directly pump coastal or underground seawater using electric motors and pump facilities unless artificially manufactured and supplied seawater, and it is common to use a blower or aeration tower as the oxygen supply device. Filtration and effluent treatment systems are widely used as water treatment apparatus for sedimentation and removal of suspended solids using gravity.

However, the conventional circulating aquaculture system has a disadvantage that the entry barrier is economically and administratively very high in a small-scale aquaculture plant, because it uses a complex equipment process and a high-cost membrane filter to filter suspended substances.

In addition, it is difficult to use the existing facilities, and it is possible to install them all as new facilities, and there is a disadvantage in that it is required to continuously replace facilities by designing a physical filtration center system.

Korean Patent Publication No. 10-2017-0022051

The present invention was devised to solve the above problems, and its purpose is to provide a circulating filtration system of a microbial filtration center system design with little facility replacement by decomposing and removing foreign matter using microorganisms.

To this end, the process of minimizing the concentration of organic matter in the raw water flowing into the microbial filtration device is the most important, so the purpose is to provide a circulating filtration system having a swirl-skimmer filtering method that minimizes clogging of the microbial filtration device. have.

In addition, it is an object of the present invention to provide a circulating filtration system composed of a lattice-type water tank that can significantly reduce stress and disease transmission of farmed fish by easily removing organic matter at the bottom of the farm.

As a result, it is prevented from increasing the amount of return due to frequent return to remove organic matters such as viscous feed residues, feces, and bio-flocks generated in aquaculture tanks. The purpose is to provide aquaculture systems.

In addition, it is easy to remove organic matter at the bottom of the farm using a grid-type water tank, and it prevents an increase in the amount of return due to frequent water exchange for removing organic matter such as viscous feed residues, feces, and bio-flocks generated in the farm. Therefore, the purpose is to provide a low-circulation circulation method for supplementing only the shortage due to evaporation and organic matter discharge.

In order to achieve the above objects, in the present invention, a vortex filter for supplying aquaculture water containing a foreign material at a predetermined flow rate to create a vortex, and separating the separated foreign matter to primarily filter the aquaculture water, and the vortex filter Decomposition and decomposition of foreign substances by using the biological action of microorganisms by receiving the primary filtered aquaculture water and filtering the secondary by using the floating principle of water bubbles and the secondary filtered aquaculture water from the skimmer filter. It includes a bio-filter to remove, and a grid-type water tank composed of a plurality of water tanks divided into a lattice form to facilitate removal of organic substances at the bottom while receiving the aquaculture water from which the foreign matter has been decomposed and removed by microorganisms. Water vortex filter, skimmer filter, bio filter, lattice tank sequentially It provides a low-return circulation culture system using microorganisms having a low-return circulation method to compensate for the shortage due to evaporation and organic matter discharge in the lattice-type water tank while circulating.

The vortex filter creates a vortex in the inlet pipe through which the aquaculture water flows, and the aquaculture water flowing in from the inlet pipe, moves the foreign substance from the shaft to the outside in a centrifugal state, separates it, precipitates through the lower opening, and separates the foreign substance. A vortex chamber for discharging cultured water in a vertical direction, a sedimentation port for sedimentation of foreign substances through the opening, a filtration filter for filtering aquaculture water from which foreign substances have been separated from the vortex chamber, and a cultured filter through the filtration filter It may include a discharge pipe for discharging water.

The inlet pipe may be connected in a tangential direction to the vortex chamber so that the cultured water flowing into the vortex chamber can induce a more smooth swirling vortex flow inside the vortex chamber.

In addition, the bio-filter may be configured such that a plurality of filtration tanks are partitioned in parallel to undergo a filtration process step by step.

In the present invention, it is connected to the outlet pipe provided in the vortex filter may further include a transfer pump for pumping aquaculture water to the skimmer filter.

Meanwhile, the lattice-type water tank may be divided into a plurality of water tanks through a detachable lattice partition plate.

The lattice divider is divided into a vertical divider and a horizontal divider, and a coupling groove is provided in the upper or lower portions of the vertical divider and the horizontal divider to enable coupling when the vertical divider and the horizontal divider are crossed at right angles. It is characterized by being formed.

The lattice partition plate has a structure capable of selectively sealing or opening in the lattice-type water tank, so that adjacent water tanks can be communicated when necessary.

In addition, the lattice-type water tank is formed with a fitting groove capable of fitting the lattice partition plate on an inner surface, thereby allowing the lattice partition plate to be closed or opened in the lattice-type water tank by selectively inserting or releasing the lattice partition plate into the fitting groove. It has a structure.

Here, a plurality of the fitting grooves are formed at regular intervals on the inner surface of the grid-like water tank, and it is possible to vary the size of the water tank according to the position of the fitting groove to fit the grid partition plate.

In addition, a bottom groove capable of fitting the grid divider plate is formed on the bottom surface of the grid-like tank, and when the grid divider plate is fitted into the bottom groove, each tank is sealed to prevent disease transmission.

On the other hand, in order to achieve the above object, in the present invention, the primary filtration step of sedimentation of the foreign matter by using a vortex filter that generates a vortex by supplying aquaculture water containing a foreign material at a predetermined flow rate, and in the vortex filter 1 Secondary filtration step of receiving the filtered filtered water by using a skimmer filter using the floating principle of underwater bubbles, and biofilter is supplied with the second filtered filtered water to utilize the biological action of microorganisms Fish in a lattice-type water tank composed of a plurality of water tanks separated by a lattice to facilitate removal of organic substances at the bottom while receiving a third filtration step to decompose and remove the foreign substances, and to receive aquaculture water from which microorganisms have been decomposed and removed. Including breeding step, the cultured water swirl filter, skimmer filter, bio filter, grating The low water exchange method circular form while circulating the water tank sequentially using microorganisms having a low water exchange rotating basis to replenish shortages only by said lattice-type water bath, and evaporated organic material discharge is provided.

According to the present invention as described above, it is very economical because it is possible to save operating maintenance costs because the replacement of facilities is rarely generated through the design of a microbial filtration center system using microorganisms rather than physical filtration.

In addition, the Swirling-Skimmer filtering method that minimizes clogging of the microbial filtration device and the lattice-type water tank that facilitates removal of organic matter at the bottom make it easier to clean organic matter such as debris generated in the aquaculture tank, and fish and shellfish in a hygienic environment. There is an effect that can form.

In addition, there is an effect of preventing the increase in the amount of return in the aquaculture tank to enable low-return circulation aquaculture to compensate only for the shortage due to evaporation and organic matter discharge.

1 is a block diagram showing the overall configuration of a low-water circulation culture system using the microorganism of the present invention.
2 is a cross-sectional view showing an embodiment of the vortex filter of the present invention.
3 is a cross-sectional view showing an embodiment of the bio filter of the present invention.
Figure 4 is a perspective view showing an embodiment of a grid-like water tank of the present invention.
5 is an exploded perspective view showing an embodiment of a grid-type water tank of the present invention.
6 is a combined perspective view of the inner space of the grid-shaped water tank in FIG. 4 differently.
7 is an exploded perspective view showing another embodiment of the lattice-type water tank of the present invention.
8 is a combined perspective view of FIG. 7.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only the present embodiments allow the disclosure of the present invention to be complete, and the scope of the invention to those skilled in the art is completely It is provided to inform you.

1 is a block diagram showing the overall configuration of a low-circulation circulation culture system using microorganisms of the present invention, FIG. 2 is a cross-sectional view showing an embodiment of the vortex filter of the present invention, and FIG. 3 is a bio-filter of the present invention 4 is a perspective view showing one embodiment of a lattice-type water tank of the present invention, and FIG. 5 is an exploded perspective view showing one embodiment of a lattice-type water tank of the present invention.

The low-circulation circulation culture system using microorganisms of the present invention includes a vortex filter 100, a skimmer filter, a bio-filter 200, and a lattice-type water tank 300 divided into lattice shapes.

The vortex filter 100 is a device for supplying aquaculture water containing a foreign material at a predetermined flow rate to create a vortex, and slowing down the vortex to settle separated foreign matter to primarily filter the aquaculture water, which is proposed in the present invention. As shown in FIG. 2, the vortex filter creates a vortex in the inflow pipe 110 through which the aquaculture water flows, and the aquaculture water flowing in from the inflow pipe 110, thereby moving the foreign matter from the axis to the outside in a centrifugal state to separate it. After that, the vortex chamber 120 for sedimenting through the opening 122 at the bottom and discharging the cultured water from which the foreign matter has been separated in the vertical direction, the sedimentation port 130 for precipitating foreign matter through the opening, and the vortex chamber ( 120) to include a filtration filter 140 for filtering aquaculture water from which foreign substances have been separated, and an outlet pipe 150 for discharging filtered aquaculture water through the filtration filter 140 You can.

The filtration filter 140 is formed on an upper portion of the vortex chamber 120, and a through hole is formed between the filtration filter 140 and the vortex chamber 120 so as to discharge the cultured water separated by foreign matter in the vertical direction. .

Here, the inlet pipe 110 is preferably connected in a tangential direction with the vortex chamber 120 so that the cultured water flowing into the vortex chamber 120 can induce a more smooth swirling vortex flow inside the vortex chamber. Do.

In the present invention, although the vortex filter 100 having the above-described configuration is proposed, it is also possible to apply a known configuration as long as it is a vortex filter having a structure capable of sedimenting / separating foreign substances generated in the culture tank using the vortex.

As described above, the cultured water primarily filtered from the vortex filter 100 is supplied to the skimmer filter. In this case, a transfer pump P is connected to the outlet pipe 150 provided in the vortex filter 100 to be configured to pump aquaculture water with the skimmer filter.

The skimmer filter serves to receive the first filtered aquaculture water and filter the second.

The skimmer filter is a device that receives primary filtered water from a vortex filter and filters it secondarily using the floating principle of air bubbles. It is made in the form of a closed tank, and the farmed water is introduced into one end and the other end. The outflow supply pipe and the outflow pipe are provided, and a skimmer screen for filtering foreign substances may be formed therein. However, in the present invention, the skimmer filter can be applied in various forms.

As described above, the cultured water filtered by sedimenting the foreign matter first may be introduced into the skimmer filter in a state in which many foreign matters have already been removed when supplied to the skimmer filter.

On the other hand, the second filtered water from the skimmer filter flows into the bio filter 200 that decomposes and removes foreign substances by using the biological action of microorganisms.

The bio filter 200 is a filter for purifying secondary filtered aquaculture water using various microorganisms. As shown in FIG. 3, a plurality of filtration tanks are installed in parallel to perform a filtration process step by step.

The filtration tank can be configured in various ways. That is, since the bio-filter 200 of the present invention processes aquaculture water using microorganisms, the biological treatment is directly related to and differentiates from the performance of microorganisms, and the configuration of the filtration tank can be variously applied.

In one embodiment of the present invention, four filtration tanks 210, 220, 230, and 240 were constructed in parallel. Here, the first and second filtration tanks were composed of anaerobic (oxygen-free) filtration tanks, and the third and fourth filtration tanks were composed of aerobic filtration tanks and aeration tanks capable of high-level treatment to divide them in parallel.

Specifically, the first filtration tank 210 is an anaerobic filtration tank that receives form water from the lower side, passes through a filter 211, adsorbs and removes suspended solids through the porous inorganic filtration media layer 212, and then removes the first moving tube ( It is configured to drop supply to the second filter tank 220 through 213).

The second filtration tank 220 is an anaerobic filtration tank (anoxic tank) that receives the first filtered water, passes through the filter 221, passes through a porous inorganic filter media layer 222 having cation exchange characteristics, and completes denitrification by inducing cation exchange. After the second moving tube 223 is configured to supply the drop to the third filter tank 230.

In addition, the third filtration tank 230 is an aerobic filtration tank, and is configured to decompose residual organic matter and SS by microorganisms attached to the carrier while flowing the carrier 231 capable of mass-proliferating aerobic microorganisms in the tank. . The filtered water that has undergone such a process is configured to drop and supply to the fourth filtering tank 240 through the third moving tube 233.

Meanwhile, the fourth filtration tank 240 is an aeration tank, receives oxygen from an oxygen supply device, and simultaneously adjusts the pH (pH) of the filtered water, reduces the BOD, and COD to perform advanced treatment, and then forms the filtered water discharge port 242 formed thereon. It is configured to be discharged through.

As described above, the low-return circulation culture system of the present invention can be applied as a microbial filtration center system with little facility replacement by decomposing and removing foreign substances using microorganisms.

As described above, the cultured water through which the foreign substances are decomposed and removed by microorganisms in the bio filter 200 through the vortex filter 100 and the skimmer filter is supplied to the lattice-type water tank 300.

The lattice-type water tank 300 is supplied with aquaculture water from which the foreign matter has been decomposed and removed by the microorganisms in the bio-filter 200, and is composed of a plurality of water tanks divided in a lattice form so as to easily remove organic substances at the bottom.

Since the tanks for breeding fish are formed in a grid-separated form, each tank can be managed separately, so it is easy to remove organic matter at the bottom of the farm, which can significantly reduce stress and disease transmission of farmed fish.

The lattice-type water tank 300 may be divided into a plurality of water tanks through the detachable lattice partition plates 320 and 330.

The grid divider is divided into a vertical divider 320 and a horizontal divider 330, and the grid-like water tank 300 is formed with a fitting groove 312 capable of fitting the grid divider on the inner surface. The plurality of water tanks in the grid-like water tank 300 can be made solid by inserting or leaving the grid partition plate into the fitting groove 312.

In one embodiment of the present invention, the coupling grooves 322 (at the upper or lower portions of the vertical divider 320 and the horizontal divider 330) can be coupled by intersecting the vertical divider and the horizontal divider at right angles. 332) is formed.

As shown in the drawing, the coupling grooves 322 and 332 are formed at about half the height of the vertical divider 320 or the horizontal divider 330, while crossing the vertical divider and the horizontal divider at right angles. It is formed from the contact surface to fit.

Of course, it is also possible to use either the vertical divider 320 or the horizontal divider 330 as the grid divider. In this case, since the coupling groove is not formed in the vertical partition plate 320 or the horizontal partition plate 330, sealing is possible in a water tank formed of a grid.

In addition, although not shown in the drawings, the grid divider plate is made of the same width as each of the plurality of tanks, and by having a structure capable of coupling adjacent grid dividers to each other at the edge of each grid divider plate, It is also possible to form a plurality of grid-like water tanks by cross-linking the grid dividers in the vertical and horizontal directions.

In this case, a known technique, for example, a concavo-convex structure, may be applied to the structure for combining the respective grid dividers. The lattice partition plates 320 and 330 have a structure capable of being selectively sealed or opened in the lattice-type water tank 300, so that adjacent water tanks can be communicated when necessary.

Meanwhile, a plurality of the fitting grooves 312 are formed at regular intervals on the inner surface of the grid-like water tank 300, and the sizes of the water tanks are variously formed according to the position where the grid partition plates are fitted to the fitting grooves 312. It is possible to do.

6 is a combined perspective view of the inner space of the grid-like water tank differently formed in FIG. 4, the number of vertical dividers 320 or the horizontal dividers 330, the vertical dividers 320 or the horizontal dividers 330 Depending on the location of the fitting groove 312 to be fitted, a variety of sizes and numbers of grid-like water tanks can be formed.

7 is an exploded perspective view showing another embodiment of the lattice-type water tank of the present invention, and FIG. 8 is a combined perspective view of FIG. 7.

In another embodiment, the grid-like water tank 400 is formed with a fitting groove 412 capable of fitting the grid-dividing plate 420 and 430 on an inner surface, and a bottom surface 414 of the grid-like water tank 400. ) Also has a structure in which the bottom groove 416 capable of fitting the grid dividers 420 and 430 is formed.

In the grid-like water tank 400, since the grid partition plates 420 and 430 are simultaneously fitted to the fitting groove 412 and the bottom groove 416, the sealing force of each tank becomes stronger, thereby preventing disease transmission. Can be improved.

The low-return circulation culture method using the low-recirculation circulation aquaculture system of the present invention configured as described above is primary filtration for sedimentation of foreign substances by using a vortex filter 100 that generates vortex by supplying aquaculture water containing foreign substances at a predetermined flow rate. Step and a second filtration step of receiving the filtered water primarily filtered from the vortex filter 100 and using a skimmer filter using the floating principle of air bubbles to filter the second, and the filtered second filtered water A third filtration step in which the bio-filter 200 is supplied to decompose and remove foreign substances by using the biological action of the microorganism, and is supplied with aquaculture water from which the foreign substances have been decomposed and removed by the microorganism, and it is provided in a lattice form to facilitate removal of organic substances on the floor And breeding fish in a lattice-type water tank 300 composed of a plurality of water tanks separated by.

As described above, since the aquaculture water can circulate through a vortex filter, a skimmer filter, a bio filter, and a lattice-type tank sequentially, the shortage due to evaporation and discharge of organic matter in the lattice-type tank can be compensated, so that fish farming is possible with a low-return circulation method. Do.

In addition, the tanks for breeding fish are made in a lattice form, so that each tank can be managed separately while operating a large farm using a large-capacity tank, so it is easy to remove organic substances at the bottom and problems such as the possibility of disease transmission. There is an advantage that can be solved.

In addition, a grid-type water tank can be configured by variously applying a grid partition plate, and by having a structure capable of opening each grid partition plate, there is an advantage of allowing communication with adjacent tanks when necessary.

The low-circulation circulating aquaculture system using the microorganism of the present invention configured as described above circulates the aquaculture water in a vortex filter, skimmer filter, bio-filter, and lattice tank sequentially while supplementing only the shortage due to evaporation and organic matter discharge in the lattice-type tank. Since it is possible, the amount of return can be significantly reduced compared to the conventional technique.

Therefore, there is an effect that can solve the conventional problems that are constantly exposed to risks due to the increase in the amount of return due to the increase in cost due to the heating / cooling operation and the introduction of parasites, red tides, viruses, and disease sources when entering seawater.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

100: swirl filter 110: inlet pipe
120: vortex chamber 122: opening
130: settling port 140: filtration filter
150: outlet pipe 200: bio filter
210: first filtration tank 220: second filtration tank
230: third filtration tank 240: fourth filtration tank
300: grid tank 312: fitting groove
320, 330: Grid divider 322, 332: Coupling groove

Claims (15)

A vortex filter that supplies aquaculture water containing foreign substances at a predetermined flow rate to create a vortex, and primarily filters the aquaculture water by sedimenting the separated foreign substances;
A skimmer filter that receives the first filtered water from the vortex filter and filters it secondarily using the principle of floating water in the air bubbles;
A bio filter that decomposes and removes foreign substances by using the biological action of microorganisms by receiving the second filtered filtered aquaculture water from the skimmer filter; And
A grid-type water tank for breeding fish by receiving aquaculture water from which the foreign matter has been decomposed and removed by microorganisms from the biofilter, and discharging the aquaculture water back into a swirl filter;
It includes,
The lattice-type water tank can be divided into a plurality of water tanks through a detachable lattice dividing plate, so that each water tank can be managed separately, and a fitting groove capable of fitting the lattice dividing plate is formed on the inner surface thereof, and the bottom surface is formed. Also, a bottom groove capable of fitting the grid divider is formed, and when the grid divider is inserted into the fitting groove and the bottom groove, each tank is sealed to prevent disease transmission.
A structure capable of bonding adjacent grid dividers to each other is formed at an edge of the grid divider, thereby cross-linking the grid dividers in the vertical and horizontal directions to form a plurality of grid-like tanks, thereby forming a grid-like tank within the grid-like tank. Optional sealing or opening is possible, so it is possible to operate a variable variable tank in which adjacent water tanks are connected if necessary.
The bio-filter is composed of a plurality of filtration tanks in an order of anaerobic filtration tank, aerobic filtration tank, and aeration tank in parallel, so that the filtration process is performed step by step. It is supplied to the filtration tank, and the aeration tank receives oxygen from the oxygen supply device, and at the same time, adjusts the pH (pH) of the filtered water, reduces the BOD, and COD, and then performs advanced treatment to discharge it through the filtered water discharge port formed on the upper side. It is configured to supply to the mold tank,
Low-circulation circulation culture system using microorganisms having a low-recirculation circulation method to compensate for the shortage due to evaporation and discharge of organic substances in the lattice-type water tank while sequentially circulating the aquaculture water filter, skimmer filter, bio filter, and lattice-type water tank. The method according to claim 1, The vortex filter,
An inflow pipe through which aquaculture water flows,
A vortex chamber that creates a vortex in the aquaculture water introduced from the inlet pipe, moves the foreign matter from the axis to the outside in a centrifugal state, separates it through an opening in the lower part, and discharges the aquaculture water from which the foreign matter is separated vertically.
A sedimentation port for sedimenting foreign matter through the opening,
A filtration filter for filtering aquaculture water from which foreign substances have been separated from the vortex chamber,
A low-circulating water circulation culture system using microorganisms including an outlet pipe for discharging filtered water through the filtration filter. The method according to claim 2,
The inlet pipe is a low-circulation circulation culture system using microorganisms, characterized in that the aquaculture water flowing into the vortex chamber is connected in a tangential direction with the vortex chamber so as to induce a more smooth swirling vortex flow inside the vortex chamber. delete The method according to claim 1,
Low-circulation circulation culture system using microorganisms, characterized in that it further comprises a transfer pump for pumping aquaculture water to the skimmer filter is connected to the outlet pipe provided in the vortex filter. delete delete delete delete The method according to claim 1,
A plurality of fitting grooves are formed at regular intervals on the inner surface of the grid-like water tank,
Low-circulation circulation culture system using microorganisms, characterized in that it is possible to variously form the size of the water tank according to the position of the fitting groove to fit the grid divider. delete A primary filtration step of sedimenting the foreign matter using a vortex filter that supplies aquaculture water containing the foreign material at a predetermined flow rate to create a vortex;
A second filtration step of receiving the filtered water primarily from the vortex filter and secondarily filtering it using a skimmer filter using the principle of floating water in the air bubbles;
A third filtration step in which the second filtered aquaculture water is supplied by a bio filter to decompose and remove foreign substances by using the biological action of microorganisms; And
Breeding fish in a lattice-type water tank that is supplied with aquaculture water from which the foreign matter has been decomposed and removed by microorganisms in the biofilter, and is composed of a plurality of water tanks separated by a grid;
Including the step of circulating by discharging the cultured water back to the vortex filter in the grid-type water tank,
The lattice-type water tank can be divided into a plurality of water tanks through a detachable lattice dividing plate, so that each water tank can be managed separately, and a fitting groove capable of fitting the lattice dividing plate is formed on the inner surface thereof, and the bottom surface is formed. Also, a bottom groove capable of fitting the grid divider is formed, and when the grid divider is inserted into the fitting groove and the bottom groove, each tank is sealed to prevent disease transmission.
A structure capable of bonding adjacent grid dividers to each other is formed at the edge of the grid divider, thereby cross-linking the grid dividers in the vertical and horizontal directions to form a plurality of grid-like tanks, thereby forming a grid-like tank within the grid-like tank. Optional sealing or opening is possible, so it is possible to operate a variable variable tank in which adjacent water tanks are connected if necessary.
The bio-filter is composed of a plurality of filtration tanks in an order of anaerobic filtration tank, aerobic filtration tank, and aeration tank in parallel, so that the filtration process is performed step by step. It is supplied to the filtration tank, and the aeration tank receives oxygen from the oxygen supply device, and at the same time, adjusts the acidity (pH) of the filtered water, reduces the BOD, and COD, and then performs high-level treatment. It is configured to supply to the mold tank,
A method for circulating low-water circulation using microorganisms having a low-return circulation method to supplement the shortage due to evaporation and organic matter discharge in the lattice-type water tank while sequentially circulating the aquaculture water filter, skimmer filter, bio-filter, and lattice-type water tank. delete delete delete

Images