KR102496109B1 - Shrimp farm - Google Patents

Abstract

The present invention relates to shrimp farming with a device and structure that effectively collects sludge, which is bound to accumulate on the bottom over time, and easily discharges the sludge to the outside. The shrimp farm, according to the present invention, comprises: a sludge settling area having an inward-cut shape so that the sludge settles in the center part of the bottom; at least one underwater pump sucking in surrounding water to discharge the water through an outlet and disposed around the sludge settling area; an underwater support; and a plurality of venturi pipes installed on the underwater support, connected to the outlet of the underwater pump to discharge water flowing in through the outlet, and introducing air from the outside according to a pressure difference according to the transmission of the water to discharge the air together with the water, wherein the plurality of venturi pipes are disposed between the underwater pump and an inner wall of the shrimp farm.

Description

Shrimp Farm{SHRIMP FARM}

The present invention relates to a shrimp farm, and more particularly, to a shrimp farm including devices and structures for maximally preventing water contamination.

Dissolved oxygen is one of the most important factors affecting stocking density and yield in shrimp farms.

Low oxygen levels impede the health and viability of shrimp farming while limiting nitrifying bacteria that break down organic waste.

Therefore, in aquaculture production, this problem has been solved somewhat by supplying air to the farm from waterwheels to airstones to create the familiar bubbles commonly found in shrimp farms.

Thus, the traditional concept of aeration in fish farms is to physically agitate the surface of the water so that atmospheric oxygen dissolves in the top layer of water.

However, there is a problem in that the bubbles caused by the old-style aeration device of this method quickly rise to the surface, and most of the dissolved oxygen is concentrated in the water of the uppermost layer, not the middle and lower layers of the water, where most farmed shrimp spend the day.

As a result, the lack of oxygen at the bottom prevents aerobic nitrifying bacteria from decomposing the waste, creating a layer of sludge that retains various pathogens while rapidly deteriorating water quality.

Shrimp farms also accumulate a lot of organic matter during aquaculture production from uneaten feed, fertilizer, excrement, carcasses and dead phytoplankton, all of which settles to the bottom of the farm tank in the form of sediment or sludge.

Such unmanaged sludge can cause many problems such as increased ammonia levels, reduced dissolved oxygen (DO) and rapid water quality degradation.

Therefore, in order to ensure good water quality and optimal shrimp health, good farm floor management is necessary. Ultimately, reducing the pollution level by effectively discharging sludge to the outside is a way to improve the growing environment of shrimp and lower the mortality rate of shrimp. Furthermore, productivity can be improved by increasing the ratio of available shrimp habitat.

Registered Utility Model No. 20-0355346

The present invention has been made to solve the above conventional problems, and its purpose is to effectively collect sludge that inevitably accumulates on the bottom over time and to easily discharge it to the outside. A shrimp farm with a device and structure is to provide

In order to achieve the above object, the shrimp farm according to the present invention includes a sludge seating area having a recessed shape so that the sludge is seated at the center of the floor; at least one submersible pump that sucks in surrounding water and discharges it through an outlet and is disposed around the sludge seating area; an underwater support; A plurality of devices installed on the submersible support and connected to the outlet of the submersible pump to drain the water flowing in through the outlet and to inflow air from the outside according to the pressure difference according to the transmission of the water to flow out together with the corresponding water. It includes a Venturi tube, and the plurality of Venturi tubes may be disposed between the submersible pump and the inner wall of the shrimp farm.

Here, an underwater step for blocking the flow of water from the sludge seating area to the submersible pump may be further provided on the floor between the submersible pump and the sludge seating area.

Here, the Venturi tube includes a first Venturi tube disposed at the lower end of the underwater support and a second Venturi tube disposed above the first Venturi tube, and the outlet pipe of the first Venturi tube is the sludge It may be directed toward the seating area.

Here, the underwater support may be disposed at a position spaced apart from the inner wall of the shrimp farm.

Here, the submersible pump may be arranged in a form wrapped in a net to prevent the inflow of shrimp fry.

As described above, according to the present invention, the combination of the pump water pulling force and the discharge force of the Venturi tube can easily push foreign substances that are precipitated or can be precipitated into the sludge seating area corresponding to the center of the shrimp farm.

In addition, by performing the function of supplying dissolved oxygen together with the function of collecting sludge, it is possible to minimize the occurrence of additional costs due to the separate configuration of the devices.

In other words, it is possible to supply oxygen to the farm along with efficient sludge removal, which can greatly help achieve the performance of the aquaculture business by maintaining clean aquaculture water and optimizing FCR (Food Conversion Efficiency). It also has the effect of significantly reducing the risk of mortality.

1 is a front cross-sectional view of a shrimp farm according to an embodiment of the present invention;
2 is a schematic diagram showing the relationship between the submersible pump and the venturi tube configured in FIG. 1;
Figure 3 is a schematic view of the shrimp farm of Figure 1 viewed from above,
4 is an example of a water flow direction generated in a shrimp farm according to an embodiment of the present invention,
5 is an example of sludge collected in a shrimp farm according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, each embodiment according to the present invention is only one example to aid understanding of the present invention, and the present invention is not limited to these embodiments. In particular, the present invention may be configured as a combination of at least one or more of individual components and individual functions included in each embodiment.

The overall cross-sectional structure of the shrimp farm according to an embodiment of the present invention is as shown in FIG.

As shown in the figure, the shrimp farm according to one embodiment of the present invention may include a sludge seating area 100, a submersible pump 200, an underwater support 300, and a venturi tube 400.

Here, the sludge seating area 100 is formed at the center of the bottom of the shrimp farm, and is an area having a shape dug inward to allow the sludge 101 to settle there.

As shown in FIG. 1, a separate piping system is formed below the sludge seating area 100 to discharge the sludge 101 to the outside.

Here, the piping system includes a pipe 110 connected to the sludge seating area 100 and a motor (not shown) connected to the pipe 110 to forcibly discharge the sludge 101 to the outside. Since the device itself for discharging foreign substances to the outside corresponds to a known technology, a detailed description thereof will be omitted.

Of course, the sludge 101 accumulated in the sludge seating area 100 may be manually discharged to the outside through a predetermined pump or the like even if there is no such piping system. The important thing is to collect the sludge 101 so that it can be concentrated in the sludge seating area 100 without being accumulated over the entire floor in the shrimp farm, and discharging the accumulated sludge 101 itself is a known technique You can use

The submersible pump 200 sucks in surrounding water and discharges it through a predetermined discharge port, and is disposed around the aforementioned sludge seating area 100.

A plurality of these submersible pumps 200 may be arranged in a shrimp farm.

Since the function of the submersible pump 200 to suck in and discharge water to the outlet and its structure itself correspond to well-known technologies, a detailed description thereof will be omitted.

However, in this embodiment, one characteristic is that a plurality of such submersible pumps 200 are disposed around the sludge seating area 100 formed in the center of the shrimp farm.

In particular, since the submersible pump 200 sucks the water around the pump function, the shrimp fry in the shrimp farm can be sucked in with the water, so it can be arranged in a form wrapped in a net to prevent the inflow of the shrimp fry.

Specifically, as shown in FIG. 2, the submersible pump 200 may be contained in a predetermined metal container (eg, stainless steel case) 230. At this time, by covering the net 220 around the metal container, the underwater Inflow into the pump 200 can be prevented.

Of course, at this time, the discharge pipe 211 connected to the outlet 210 of the submersible pump 200 may pass through the net 220, and the penetration part is well sealed to prevent the inflow of young shrimp.

For reference, after installing the pump support 240 at the lower end of the metal cylinder 210, the submersible pump 200 may be fixedly mounted on the pump support 240.

Meanwhile, an underwater step 201 may be further provided on the bottom between the submersible pump 200 and the sludge seating area 100 to block the flow of water from the sludge seating area 100 to the submersible pump 200.

That is, as described above, the submersible pump 200 performs a function of sucking in surrounding water and discharging it through the outlet. At this time, if there is no obstacle, the water in the next sludge seating area 100 is also sucked in.

However, when an underwater step 201 is formed on the floor between the submersible pump 200 and the sludge seating area 100, the flow of water from the sludge seating area 100 toward the submersible pump 200 is blocked, and the other direction The flow of water from to the submersible pump 200 is generated.

This eventually forms a flow of water directed toward the sludge seating area 100 as a whole within the shrimp farm. Therefore, the presence of such an underwater step 201 is very important.

The height of the submersible step 201 is preferably configured not to be higher than the height of the submersible pump 200.

In addition, the underwater step 201 may be constructed directly on the bottom of the shrimp farm, but, for example, when the submersible pump 200 is installed on a predetermined floor support, the underwater step 201 may be formed on such a floor support is of course

As will be described later, the underwater support 300 allows the Venturi tube 400 to be mounted, and may be formed in a form rising upward from the bottom of the shrimp farm, and the number may be plural.

For example, a plurality of Venturi tubes 400 may be mounted on the underwater support 300. At this time, the Venturi tubes 400 may be mounted using a predetermined clamp, and the connection structure itself corresponds to a known technology. Therefore, a detailed description is omitted.

However, in order to achieve both sludge collection and oxygen supply effects, the first venturi pipe 410 is mounted under the underwater support 300, and the second venturi pipe 410 is installed at a higher position than the first venturi pipe 410. A tube 420 is preferably installed. A more detailed description of this will be described later.

This underwater support 300 may be disposed at a position spaced apart from the inner wall of the shrimp farm.

Shrimp fry have a habit of sticking to the inner wall of the shrimp farm. The venturi tube 400 is installed on the inner wall of the shrimp farm without the underwater support 300, or the underwater support 300 is installed almost attached to the inner wall of the shrimp farm. In this case, since the water / air pressure flowing out of the venturi pipe 400 may adversely affect the shrimp fry clinging to the inner wall of the shrimp farm, the underwater support 300 is placed at a position spaced apart from the inner wall of the shrimp farm (eg For example, it is preferable to place it at a location separated by 1 m or more).

As described above, the venturi pipe 400 is installed on the submersible support 300, and is connected to the outlet 210 of the submersible pump 200 through a predetermined connection pipe 401 through the connection pipe 401. It performs the function of draining the inflowing water through the other outlet.

At this time, an air inlet pipe 402 may be further connected to the venturi pipe 400, and performs a function of introducing air from the outside through the air inlet pipe 402 according to a pressure difference due to water transfer and flowing it out together with the corresponding water. do.

That is, the venturi pipe 400 discharges the water introduced through the connection pipe 401 and the air introduced through the air inlet pipe 402 together through the outlet, and the structure itself exhibiting the venturi effect is known in the art. , so a detailed description is omitted.

However, it is preferable in terms of oxygen supply that the radius of the Venturi effect generating area, which is located between the portion where the connecting pipe 401 is connected and the portion connected to the air inlet pipe 402 and exhibits the Venturi effect, is 1 mm to 2 mm.

In particular, a plurality of venturi tubes 400 may be provided for each support installed in the shrimp farm. In this embodiment, the first venturi tube 410 is installed at the lower end, As an example, the second venturi tube 420 is installed at a higher position of the underwater support 300.

For example, the first Venturi tube 410 may be installed at the lower end of the underwater support 300, and the second Venturi tube 420 may be installed at the middle or upper end of the underwater support 300.

At this time, it is preferable that the direction of the outflow pipe of the first venturi pipe 410 is directed toward the sludge seating area 100.

That is, one of the main features of the present invention is to move and gather contaminants accumulated on the bottom or toward the bottom, that is, materials that eventually gather and become sludge, to the sludge seating area 100, and as described above, the underwater step ( 201) and the water pump 200, the flow of water heading to the sludge seating area 100 by the first Venturi pipe 410 is combined with the flow of water formed in the sludge seating area 100, resulting in sludge throughout the shrimp farm A strong flow of water toward the seating area 100, that is, the central area of the shrimp farm, may be formed.

That is, even if the flow of water formed by each submersible pump 200 and the flow of water formed by the individual venturi tube 400 are weak, there are several, and furthermore, if the direction is uniform, shrimp It is possible to form a distinct flow of water throughout the farm, that is, a flow to the sludge seating area 100.

Likewise, the direction of the outflow pipe of the second Venturi pipe 420 may be directed toward the sludge seating area 100 as much as possible, but unlike the first Venturi pipe 410, the direction may be slightly twisted.

In particular, rather than directing both the first Venturi tube 410 and the second Venturi tube 420 equally toward the sludge seating area 100, the first Venturi tube 410 faces the sludge seating area 100, but , When the second venturi pipe 420 is twisted at a slight angle (for example, 5 degrees to 20 degrees) than the first venturi pipe 410, a slight difference occurs between the direction of the lower water and the upper water direction of the farm. It is preferable because it can increase the solubility of oxygen and further increase the degree of trapping of the sludge in the sludge seating area 100.

In particular, each Venturi pipe 400 should be placed between the submersible pump 200 and the inner wall of the shrimp farm. As described above, when the Venturi pipe 400 is mounted on the inner wall of the shrimp farm, the habit of sticking to the inner wall It is possible to disturb the shrimp fry with outflow water, so it is preferable that the venturi tube 400 is disposed between the submersible pump 200 and the inner wall of the shrimp farm.

This is a natural conclusion since the venturi tube 400 is mounted on the underwater support 300 when the underwater support 300 is separated.

When operating a shrimp farm having the arrangement and structure of devices as in the present invention, a considerable amount of sludge is accumulated in the sludge seating area 100, and the operator periodically discharges only the sludge accumulated in the sludge seating area 100 to the outside Therefore, it is possible to cleanly manage the water quality of the shrimp farm for a fairly long time.

For reference, FIG. 3 is a plan view showing devices and structures installed in a shrimp farm according to an embodiment of the present invention.

Looking at the figure, it can be seen that sludge is accumulated in the sludge seating area 100, which is the central area, and in particular, the periphery of each submersible pump 200 has an arc shape, and the underwater step 201 is formed as a structure. can

In addition, Figure 4 shows the flow of water formed in the shrimp farm according to an embodiment of the present invention, and it can be seen that the flow of water is gradually formed in the center of the water like a whirlwind.

5 is an example of the type of sludge accumulated in the sludge seating area 100 according to the present invention, which affects the water quality management of shrimp farms depending on how efficiently the sludge is discharged.

In addition, the present invention is not limited to the specific embodiment described above, but can be implemented by various modifications and variations within the scope of the present invention. It will be apparent that such variations and modifications are included in the present invention provided they come within the scope of the appended claims.

100: sludge seating area 200: submersible pump
300: underwater support 400: Venturi tube
201: underwater step 410: first venturi tube
420: second venturi tube

Claims (5)

delete In shrimp farms,
a sludge seating area having a shape dug inward so that the sludge is seated at the center of the floor;
at least one submersible pump that sucks in surrounding water and discharges it through an outlet and is disposed around the sludge seating area;
an underwater support;
A plurality of devices installed on the submersible support and connected to the outlet of the submersible pump to drain the water flowing in through the outlet and to inflow air from the outside according to the pressure difference according to the transmission of the water to flow out together with the corresponding water. Including the venturi tube,
The plurality of venturi tubes are disposed between the submersible pump and the inner wall of the shrimp farm, and the bottom between the submersible pump and the sludge seating area is provided with an underwater step to block the flow of water from the sludge seating area to the submersible pump Shrimp farm, characterized in that. According to claim 2,
The Venturi tube includes a first Venturi tube disposed below the underwater support and a second Venturi tube disposed above the first Venturi tube,
Shrimp farm, characterized in that the outlet pipe of the first venturi is directed toward the sludge seating area. According to claim 3,
The underwater support is a shrimp farm, characterized in that disposed at a position spaced apart from the inner wall of the shrimp farm. According to claim 4,
The submersible pump is a shrimp farm, characterized in that arranged in a form wrapped in a net to prevent the inflow of shrimp fry.

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