KR20190023626A - Water Tank with Precipitation Tank for Removal of Particulate Solid Material - Google Patents

Abstract

The present invention provides a water tank integrated with a settling tank for removing a solid particulate matter. The water tank has the settling tank integrated to remove the particulate solid matter. The water tank integrated with the settling tank also has an airlift pump to allow feeding water to flow into the settling tank without power. So, the water tank integrated with the settling tank can efficiently remove the solid particulate matter generated in a fish farm at low costs. According to the present invention, the water tank integrated with the settling tank for removing the solid particulate matter includes: a farming water tank including a farming space; a plurality of the settling tanks integrated while being divided from the farming space at one side of the framing water tank; the airlift pump installed in the farming space adjacent to the settling tank and moving the feeding water including the solid particulate matter to the settling tank; and a discharge port discharging deposits on the bottom of the settling tank to the outside and installed on the bottom of the settling tank.

Description

Technical Field [0001] The present invention relates to a water tank for removing particulate solids,

[0001] The present invention relates to a sediment-tank integrated water tank for removing particulate solids, and more particularly, to a sediment-tank integrated water tank for removing particulate solids capable of efficiently removing particulate solids generated in a farm site at low cost .

In general, water quality in a farm is distinguished by physical factors, chemical factors and biological factors. Physical factors consist of water temperature, water content, color and transparency of water, and vary greatly depending on the topographic factors and the geological factors (material and ground condition of the fish). Chemical factors are substances that are dissolved in water, such as pH, dissolved oxygen, salt, hardness, and metabolic waste (ammonia, nitrite, nitrate, etc.). Biological factors mean various organisms that act directly or indirectly on the fish, and include various bacteria, plankton, plants and animals that live in fish culture.

Water quality, pH, DO, ammonia, nitrite, particulate solids (SS, sludge) are among the most important water quality factors in the farm.

Among important water quality factors, ammonia and nitrite have acute toxicity to fish, and when the concentration of particulate solids is high, they grow slowly and do not feed well, so they can be watered or recycled by physical and biological methods using circulation filtration equipment do.

The continuous replacement system (CRS), which is mainly used to perform aquaculture in a farm, requires a large amount of groundwater and requires a large amount of heating water because it requires high heating cost, and organic matter is discharged into the water system, There is a problem of contamination.

A recirculating aquaculture system (RAS) is used to remove the ammonia and nitrite from bacteria in the filtration tank in order to solve the heating cost and pollution problem of the breeding exchange system (CRS) (More than 200% of the aquarium volume in Korea, 20-30% in Europe) is required. In order to remove the particulate solids, an expensive drum filter (drum screen) is installed There is a problem that it must be done.

In recent years, there has been a lot of research on a biofloc (BFT) system that does not require a water tank and does not require a filtration tank.

Biofrok system is widely used in shrimp farms. It produces water used in eel farms (NH _{3 with} acute toxicity, nitrification of NO ₂ with nitrifying bacteria as low-toxicity NO ₃ ) and further carbon source (molasses, etc.) To remove the particulate solids by activating tagatinizing bacteria, denitrifying NH ₃ with N ₂ , and eating shrimp nutritional bacteria.

However, biofrok system increases the number of particulate solids including tagas nutritional bacteria when the aquatic organism is a marine creature except for the shrimp which is a protein source of a nutritional germ as a protein source. Therefore, a drum filter is installed like a purification filter system, There is also the problem of exchanging large quantities of water.

Korean Patent Publication Nos. 10-1318263, 10-1587772, 10-1621260, and 10-2014-0131411 disclose techniques for various types of fish culture devices.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and it is an object of the present invention to provide an airlift pump for removing particulate solids from a sedimentation tank, Which is capable of efficiently removing the particulate solids that can be efficiently removed at a low cost.

The sediment-tank integrated type water tank for removing particulate solids according to an embodiment of the present invention includes a culture water tank in which a breeding space is formed, and a plurality of sedimentation tanks integrally provided in a state partitioned with a breeding space on one side of the culture water tank An airlift pump installed in a breeding space in a state of being in proximity to the settling tank and moving raising water containing particulate solids to a settling tank, and an airlift pump installed on the bottom of the settling tank, As shown in FIG.

The plurality of settling tanks are formed so as to be divided into a plurality of spaces by providing a partition for the breeding water to alternately move downward and upward.

The plurality of settling tanks may be formed with a concave sloped surface or a curved surface to facilitate collection of sediments on the bottom surface.

The bubble pump is installed vertically in the breeding space in a state of being close to the first settling tank in the settling tank and is connected to the upper end of the vertical tube at a lower end portion in which an inflow hole is formed so as to allow infusion of breeding water in a breeding space, A horizontal pipe extending toward the first settling tank, and an air injection pipe installed inside the vertical pipe and injecting air into the lower end of the vertical pipe.

At the upper end of the last settling tank in the settling tank, a supernatant liquid inlet / outlet is formed so that the supernatant liquid moves toward the feeding space.

According to the tanks-integrated water tank for removing particulate solids according to the embodiment of the present invention, as the bubble pump operates, a part of the breeding water in the breeding space is moved toward the first settling tank, It is possible to efficiently remove the particulate solids contained in the raising water.

According to the embodiment of the present invention, it is possible to remove the particulate solids included in the breeding water without using an expensive drum filter, thereby realizing a low installation cost and energy saving by the sedimentation tank integrated tank for removing particulate solids It is possible to do.

In the case of using a conventional drum filter, the number of breeding water of various aquaculture tanks is collected and processed in one place, so that the possibility of transmission of diseases is high. However, according to the integrated tank for collecting tanks for removing particulate solids according to the embodiment of the present invention, Each sedimentation tank is installed to remove particulate solids, so that the possibility of disease transmission is low.

In addition, according to the present invention, it is possible to minimize the space for installing the filtration tank and the space for installing the drum filter, because the precipitation tank integrated type water tank for removing particulate solids according to the embodiment of the present invention .

1 is a front sectional view showing a sediment-tank integrated water tank for removing particulate solids according to an embodiment of the present invention.
2 is a side sectional view showing a settling tank integrated water tank for removing particulate solids according to an embodiment of the present invention.
3 is a plan view showing a sediment-tank integrated water tank for removing particulate solids according to an embodiment of the present invention.
FIG. 4 is a graph showing variation of particulate solids with time in a sediment tank integrated water tank for removing particulate solids according to an embodiment of the present invention. FIG.

Next, preferred embodiments of a sediment-tank integrated water tank for removing particulate solids according to the present invention will be described in detail with reference to the drawings.

The present invention can be embodied in various forms and is not limited to the embodiments described below.

Hereinafter, for the purpose of clearly illustrating the present invention, a detailed description of parts that are not closely related to the present invention is omitted, and the same or similar components are denoted by the same reference numerals throughout the entire description of the present invention, .

First, as shown in FIGS. 1 to 3, a settling tank integrated water tank for removing particulate solids according to an embodiment of the present invention includes a water culture tank 10, a plurality of settling tanks 20, 70, and a discharge port 90. As shown in FIG.

A breeding space is formed inside the aquaculture tank (10), and breeding water for breeding aquaculture is filled.

The plurality of settling tanks (20) are integrally provided on one side of the aquarium (10) in a state of being partitioned from a breeding space.

For example, the plurality of sedimentation tanks 20 are formed integrally with the breeding space of the aquarium 10 and the partition wall 30 so that the movement of the breeding water is interrupted.

It is preferable that the sedimentation tank has a sectional area of 30% or less of the cross-sectional area of the breeding space of the aquaculture water tank 10 because the particulate solids can be efficiently removed from the breeding water.

The plurality of settling tanks 20 are formed so as to be divided into a plurality of spaces by providing a partition 40 so that the feeding water alternately moves downward and upward.

2, the partition 40 provided between the first settling tank 20 and the second settling tank 20 is provided at a lower part between the first settling tank 20 and the second settling tank 20, The water is moved to the second settling tank 20 through the lower part of the partition 40 and the partition 40 installed between the second settling tank 20 and the third settling tank 20 is installed in a state in which the lower part is in close contact with the bottom surface The partition wall 40 provided between the third settling tank 20 and the fourth settling tank 20 is constituted so as to move the second settling tank 20 to the third settling tank 20 through the upper part of the partition 40, So that the feed water of the third settling tank 20 is moved to the fourth settling tank 20 through the lower portion of the partition 40. [

In this case, the height of the upper part of the second partition 40 is lower than the height of the upper part of the first partition 40 and the upper part of the third partition 40.

As described above, by providing the partition 40 in a zigzag form, the number of the breeding water alternately moves the plurality of the settling basins 20 downward and upward.

It is preferable that the height of the partition 40 is set to be lower than the height of the partition wall 30 because the supernatant of the settling tank 20 can be prevented from moving through the partition wall 30 to the catching space.

As shown in FIG. 2, the plurality of sedimentation tanks 20 are formed with concave slopes or curved surfaces so that the sediment 4 can be easily collected on the bottom surface 24.

The concave bottom surface 24 may be formed as a single unit over the neighboring settling basins 20 when the partition 40 is installed at a distance from the bottom surface. In this case, it is possible to collect the sediment 4, which is the particulate solids precipitated in the both sedimentation tanks 20, together.

The discharge port (90) is provided on the bottom surface of the settling tank (20).

The discharge port 90 discharges the sediment 4 deposited on the bottom of the sedimentation tank 20 to the outside.

The discharge port (90) is provided with an on-off valve and is configured to open and close as required.

The outlet (90) is installed on the concave bottom surface (24) side of the settling tank (20).

At the upper end of the last settling tank 20 in the settling tank 20, a supernatant liquid inlet / outlet port 50 is formed so that the supernatant liquid moves toward the breeding space of the aquarium 10.

The upper liquid inlet / outlet 50 may be formed by forming a plurality of small-sized holes so as to prevent the organisms cultured in the breeding space from moving toward the settling tank 20, or may be constructed by installing a net.

The upper liquid inlet / outlet port (50) is installed in the partition wall (30).

The partition 40 installed close to the supernatant access port 50 is configured to have a height higher than the lower end of the supernatant access port 50 so that the supernatant liquid can pass through the supernatant access port 50, It can be prevented from moving toward the space.

In the embodiment of the present invention, as shown in FIG. 2 and FIG. 3, it is explained that the settling tank 20 is divided into four parts. However, it is also possible to provide only one partitioning part 40 to form two settling tanks 20 It is possible.

The bubble pump 70 is installed in the breeding space in a state of being close to the settling tank 20 and moves the breeding water including particulate solids to the settling tank.

The bubble pump 70 is installed in a state close to the first settling tank 20 in the settling tank 20.

The bubble pump 70 includes a vertical tube 72, a horizontal tube 74, and an air injection tube 76.

The vertical tube 72 is installed perpendicular to the breeding space of the aquarium 10 in a state of being close to the first settling tank 20.

It is preferable that the lower end of the vertical tube 72 is installed in a state of being in close contact with the bottom surface of the aquarium 10 so that the aquaculture organism can be prevented from entering the inside of the vertical tube 72.

At the lower end of the vertical tube 72, an inflow hole 73 is formed so that the breeding water of the breeding space is inflowed.

The inflow hole 73 may be formed in a small size so that no aquaculture organisms may flow into the inflow hole 73, and a plurality of inflow holes 73 may be formed.

The horizontal pipe 74 is connected to the upper end of the vertical pipe 72 and extends to the first settling tank 20.

The air injection pipe (76) is installed inside the vertical pipe (72) and is installed to inject air into the lower end of the vertical pipe (72).

If the size of the aquarium 10 is large, a bubble pump 70 is installed on the side of the central sedimentation tank 20 and the supernatant liquid inlet / It is also possible to provide them in the sedimentation tank 20 at both ends. In this case, sedimentation takes place while the water moves from the center to both sides.

Next, the operation of the integrated tank of the settling tank for removing particulate solids according to one embodiment of the present invention will be described.

First, when air is injected into the lower end of the vertical tube 72 of the bubble pump 70 through the air injection tube 76, a radiant water mixture having a light weight per unit volume is produced, The nursery mix is moved upwardly of the vertical tube 72 and discharged to the settling tank 20 through the horizontal tube 74 due to the difference in specific gravity between the nursery water and the cultivating water in the outside.

When the bubble pump 70 is operated as described above, the breeding water of the aquaculture tank 10 is moved to the settling tank 20 side. At this time, since the bred water of the bottom side of the aquarium 10 flows into the bubble pump 70, the bodily solid material is precipitated and the contained bred water flows into the settling tank 20.

The sediment transported to the sedimentation tank 20 as described above moves along the neighboring sedimentation tank 20 so that the sediment 4 as a particulate solid is settled to the bottom surface 24 of the sedimentation tank 20, .

FIG. 4 graphically shows fluctuations of particulate solids (Floc Volume) with respect to time (Time). That is, it was confirmed that the particulate solid was 0.1 mL / L after 6 hours when the treated water according to one embodiment of the present invention was applied to the cultured water having the concentration of the particulate solid of 10.0 mL / L.

As described above, it can be confirmed that the concentration of the particulate solid is effectively reduced when the embodiment of the present invention is applied.

Although the present invention has been described in connection with the preferred embodiment of the present invention, it is not limited thereto, And it is also within the scope of the present invention.

10 - Aquaculture tank, 20 - Settling tank, 24 - Bottom surface, 30 - Compartment wall, 40 - Partition
50 - Upper fluid outlet, 70 - Bubble pump, 72 - Vertical tube, 73 - Inflow hole
74 - horizontal tube, 76 - air inlet tube, 90 - outlet tube

Claims (4)

A culture water tank in which a breeding space is formed,
A plurality of sedimentation tanks integrally provided on one side of the aquarium so as to be partitioned from a breeding space,
A bubble pump installed in the breeding space in a state of being in proximity to the settling tank and moving the breeding water containing the particulate solids to the settling tank,
And an outlet for discharging sediment deposited on the bottom of the sedimentation tank to the outside, the sedimentation tank integrated tank for removing particulate solids from the sedimentation tank. The method according to claim 1,
Wherein the plurality of settling tanks are formed so as to be divided into a plurality of spaces by providing a partition for the breeding water to alternately move downward and upward,
And an upper end of the last settling tank in the settling tank is provided with a supernatant liquid inlet port for moving the supernatant liquid toward the feeding space. The method according to claim 1 or 2,
Wherein the plurality of sedimentation tanks are formed as recessed slopes or curved surfaces for easily collecting sediments on the bottom surface of the sedimentation tank integrated tank for removing particulate solids. The method according to claim 1 or 2,
The bubble pump is installed vertically in the breeding space in a state of being close to the first settling tank in the settling tank and is connected to the upper end of the vertical pipe at a lower end portion in which an inflow hole is formed so that breeding water in the breeding space is inflow A settling tank integral water tank for removing particulate solids including a horizontal pipe extending toward the first settling tank and an air inlet pipe installed inside the vertical pipe and injecting air into the lower end of the vertical pipe.

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