KR20210016932A - Sea water supply system of land fish farm based on complex arrangement pump - Google Patents

Abstract

The present invention provides a seawater supply system for an inland fish farm based on a combined arrangement of pumps. In the seawater supply system for an inland fish farm based on a combined arrangement of pumps according to the present invention, an expansion of the flux of seawater required according to an expansion of the scale of an inland fish farm enables an additional underwater auxiliary pump to be installed at a portion below the sea level of a seawater supply pipe for supplying seawater to the inland fish farm, so that the flux of seawater supplied through a simple installation of the auxiliary pump can be stably and smoothly performed while maintaining the present facilities, such as the inland fish farm and the seawater supply pipe, as they are. The stability of seawater supply to the inland fish farm can be increased by increasing the flow rate and flux of the supplied seawater according to an additional arrangement of the underwater auxiliary pump. In particular, the underwater auxiliary pump is installed at a water depth below the minimum sea level according to the ebb and flow of the water area supplying seawater to the inland fish farm, so that the underwater auxiliary pump is constantly submerged below the sea level, and a forced seawater pumping operation is performed smoothly, and thus, the operational stability of the system for seawater supply can be maximized.

Description

Sea water supply system of land fish farm based on complex arrangement pump}

The present invention relates to a complex batch pump-based onshore farm seawater supply system, and more specifically, the expansion of the supplied seawater flow rate required by the scale expansion of the onshore farm is located below the sea level of the seawater supply pipe supplying seawater to the onshore farm. By installing an additional submersible auxiliary pump, it is possible to stably and smoothly increase the flow rate of the supplied seawater through the simple installation of the auxiliary pump while maintaining the current facilities such as onshore farms and seawater supply pipes. The stability of seawater supply to onshore farms can be increased by increasing the flow rate and flow rate of the supplied seawater according to the additional arrangement of the submersible auxiliary pump. Complex batch pump-based onshore aquaculture facility that maximizes the operational stability of the system for seawater supply by performing smooth forced seawater pumping operation while keeping the submersible auxiliary pump constantly submerged under the sea level by installing it at the depth below the sea level. It relates to a seawater supply system.

The farm is a place for aquaculture of fish, seaweed, and shellfish, and is divided into a marine farm located at sea and a land farm located on land.

Since the onshore farm is located on land far from the sea, various disadvantages such as damage to the red tide, the inability to control temperature, and the inability to diversify aquaculture species can be solved. Since seawater is used in such aquaculture farms, a seawater supply system is established. As for related technologies, Korean Patent Registration No. 10-1040996 "Aquaculture for fish farming on land", registration number 10- 1329378 "Sea cucumber farming equipment" has been devised.

Such a seawater supply system consists of a seawater pump for pumping seawater into the tank of a farm, and a seawater pipeline that guides the inflow of seawater with the pumping force by the seawater pump. Here, the seawater pump is disposed in the machine room of the onshore farm, and the seawater pipe is divided into a land-side pipe passing through the land and a sea-side pipe extending so as to be submerged in the sea and connected to each other to guide the flow of seawater.

However, since the land-side pipe that forms the sea water pipe of the conventional sea water supply system is installed to pass through the underground buried passage of the road, if the land-side pipe must be changed or maintenance work is to be performed, the road is cut/dissected to the relevant road management office. In addition to obtaining permission for excavation, etc., in the case of roadways, the work must be carried out in consideration of traffic. Therefore, in fact, it was impossible to obtain permission from the management office unless replacement was performed due to damage to the onshore pipeline.

In other words, it is most desirable to increase the pipe diameter of the seawater pipe in order to supply more seawater in order to increase the capacity according to the water tank of the land aquaculture farm.However, the pipe diameter of the seawater pipe pipe could not be increased as the change of the land pipe route was practically impossible. Accordingly, in order to increase the supply of seawater, only the capacity of the seawater pump had to be increased, and the work of increasing the pipe diameter of the onshore pipeline was performed under the condition of connecting the onshore pipeline by bypassing the forest, etc. without passing through the road. This inevitably caused a rapid increase in cost.

In particular, in the case of an onshore aquaculture farm located in an area away from the beach or in an area with a large tidal difference, unlike an onshore farm located in an incision facing the sea, a seawater pump with a very large capacity due to the formation of a very long seawater pipeline. In order to further increase the seawater inflow capacity, it was inevitably required to increase the capacity of the seawater pump and motor, as well as to expand the pipe diameter of the suction pipe due to pipe resistance, and thus, the construction of replacing the pipe with a pipe with a large pipe diameter. The fact that the actual increase in the capacity of the seawater pump was not considered at all was caused by the need to be carried out in parallel.

Korean Registered Patent Publication No. 10-1040996 "Aquaculture for fish farming on land" Republic of Korea Patent Publication Registration No. 10-1329378 "Sea cucumber farming device"

Therefore, the present invention improves the problems of the prior art such that the submersible auxiliary pump installed in the water depth position below the minimum sea level according to the tidal ebb and flow of the water supplying seawater to the onshore farm and the main pump installed in the machine room of the onshore farm are seawater Through the structure that is arranged on the supply pipe, the current facilities such as the onshore farm and the seawater supply pipe are maintained as it is, and the expansion of the supply seawater flow required by the scale expansion of the onshore farm can be realized through the simple installation of the submersible auxiliary pump. It aims to provide a new type of complex batch pump-based onshore aquaculture seawater supply system.

In addition, the present invention provides a new type of complex batch pump-based onshore farm seawater supply system that maximizes the stability of seawater supply to onshore farms by increasing the flow rate and increasing the flow rate of the supplied seawater according to the additional arrangement of the submersible auxiliary pump. It aims to be.

According to the features of the present invention for achieving the above object, the present invention is a main pump 100 disposed in the machine room 4 of the onshore farm 2; A seawater supply pipe 200 connected to the main pump 100, extending below the sea level, and having an inlet 210 disposed at a set seawater inflow depth (H); An underwater auxiliary pump 300 disposed in a submerged state below the sea level and installed in the seawater supply pipe 200 at a set pump installation depth (h) position; Aquaculture plant connection pipe 400 connected to the water tank 3 of the land farm 2 to supply seawater to the water tank 3; A controller 500 that controls the operation of the main pump 100 and the submersible sub-pump 300 according to the tidal tidal information of the water body 5 in which the seawater supply pipe 200 is disposed; It provides a seawater supply system for onshore aquaculture farms based on complex batch pumps.

In such a complex batch pump-based onshore aquaculture seawater supply system according to the present invention, the pump installation depth (h) is among the time-linked sea level corresponding to the location information of the water body 5 in which the seawater supply pipe 200 is arranged. It is set to a depth value below the minimum sea level so that the submersible auxiliary pump 300 is always submerged below the sea level.

In such a complex batch pump-based onshore aquaculture seawater supply system according to the present invention, the controller 500 allows the submersible auxiliary pump 300 to operate before the main pump 100 at a set time interval t. The load of the main pump 100 may be reduced.

In such a complex batch pump-based onshore aquaculture seawater supply system according to the present invention, the seawater supply pipe 200 may be formed as a straight line in which a portion extending below the sea level is inclined.

In such a complex batch pump-based onshore aquaculture seawater supply system according to the present invention, the main pump 100 includes a seawater supply flow rate Q required by the water tank 3 of the onshore farm 2, and the underwater auxiliary It consists of a pump selected to have a pump capacity corresponding to the suction lift (H) based on the position of the pump 300,

The submersible auxiliary pump 300 is the total pump capacity required to supply the seawater supply flow rate Q required by the water tank 3 of the onshore farm 2 and the main pump 100 It can be composed of a pump selected to have a large pump capacity and a small head based on a numerical value minus the pump capacity and the head.

According to the complex batch pump-based onshore aquaculture seawater supply system according to the present invention, the expansion of the supply seawater flow rate required by the scale expansion of the onshore aquaculture is a submersible auxiliary pump at the bottom of the sea level of the seawater supply pipe supplying seawater to the onshore aquaculture. Since it is made possible by additional installation, the expansion of the flow rate of the supplied seawater is performed stably and smoothly through the simple installation of the auxiliary pump while maintaining the current facilities such as the onshore farm and the seawater supply pipe, and the additional arrangement of the submersible auxiliary pump The stability of the seawater supply to the onshore farm is increased by increasing the flow rate and flow rate of the supplied seawater according to the following conditions. In particular, the submersible auxiliary pump is installed at a depth below the minimum sea level according to the tide of the water supplying seawater to the onshore farm. In addition, the submersible auxiliary pump is constantly submerged under the sea level, and smooth seawater forced pressure delivery is performed, thereby maximizing the operational stability of the system for seawater supply.

1 is a view for showing the configuration of a complex batch pump-based onshore aquaculture seawater supply system according to an embodiment of the present invention;
Figure 2 is a view for showing the position of the submersible sub-pump under the condition of the minimum annual sea level in the combined batch pump-based onshore aquaculture seawater supply system according to an embodiment of the present invention;
3 is a view for showing a seawater supply system based on a complex batch pump according to an embodiment of the present invention applied to Jeju Island;
4 is a view for showing that the submersible auxiliary pump and the main pump are started with a time difference by a controller according to an embodiment of the present invention;
5 is a block diagram showing a tidal tidal information-based control configuration of a controller according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 5 of the accompanying drawings. On the other hand, in the drawings and detailed description, the illustrations and mentions of configurations and actions that can be easily recognized by those in the field from general onshore farms, seawater supply systems, pumps, water pumps, seawater pumps, piping, databases, etc. are simplified or omitted. I did. In particular, in the illustration and detailed description of the drawings, detailed descriptions and illustrations of specific technical configurations and actions of elements not directly related to the technical features of the present invention are omitted, and only the technical configurations related to the present invention are briefly illustrated or described. I did.

Complex batch pump-based onshore aquaculture seawater supply system 1 according to an embodiment of the present invention is a main pump 100, a seawater supply pipe 200, a submersible auxiliary pump 300, as shown in FIGS. It consists of a configuration including a pipe 400 and a controller 500.

The main pump 100 is disposed in the machine room 4 of the onshore farm 2, and the seawater supply pipe 200 and the farm connection pipe 400 are connected. The main pump 100 forcibly sucks seawater through the seawater supply pipe 200 and delivers it to the farm connection pipe 400. Here, the main pump 100 according to the embodiment of the present invention is a suction lift based on the seawater supply flow rate Q required by the water tank 3 of the onshore farm 2 and the position of the submersible auxiliary pump 300 It consists of a pump selected to have a pump capacity corresponding to (H). That is, the main pump 100 is made of a pump having a power equal to or greater than the power P calculated through the following [Equation 1] as a standard value.

P: power (kw), Q: seawater supply flow rate (M ³ /min), H: head (M), y: power transmission efficiency

The seawater supply pipe 200 is connected to the main pump 100 to extend below the sea level, and the inlet 210 forming the end portion of the seawater supply pipe 200 is disposed at the set seawater inflow depth (H). . The seawater inflow depth (H) is a value greater than the pump installation depth (h), which is set as the depth value below the minimum sea level among the visually interlocked sea levels for each season corresponding to the location information of the water body 5 in which the seawater supply pipe 200 is arranged To be set.

Here, in the seawater supply pipe 200 according to an embodiment of the present invention, a portion extending below the sea level is formed in an inclined straight line. Accordingly, when the seawater introduced through the inlet 210 flows inside the seawater supply pipe 200, the flow resistance is minimized.

Meanwhile, the seawater supply pipe 200 according to an embodiment of the present invention may be divided into a land-side pipe and an offshore pipe, so that the land-side pipe passes through the ground under the road as shown in FIG. 3.

The submersible auxiliary pump 300 is disposed in a submerged state below the sea level, and is installed in the seawater supply pipe 200 at the set pump installation depth (h). Here, the pump installation depth (h) is set to a depth value below the minimum sea level among the time-linked sea levels for each season corresponding to the location information of the water body 5 in which the sea water supply pipe 200 is arranged as shown in FIG. (300) should remain submerged below sea level at all times.

And the submersible auxiliary pump 300 according to an embodiment of the present invention is the main pump in the total pump capacity and the total head required to supply the seawater supply flow rate Q required by the water tank 3 of the onshore farm 2 It consists of a pump selected to have a large pump capacity and a small head based on the numerical value minus the pump capacity and head of (100). That is, the submersible auxiliary pump 300 according to an embodiment of the present invention is made of a pump having a standard value of high capacity and low lift.

The farm connection pipe 400 is a pipe connected to the water tank 3 of the onshore farm 2 to supply seawater to the water tank 3.

The controller 500 controls the operation of the main pump 100 and the submersible auxiliary pump 300 in accordance with the tide information of the water body 5 in which the seawater supply pipe 200 is disposed. In particular, the controller 500 according to the embodiment of the present invention is the submersible auxiliary pump 300 and the main so that the submersible auxiliary pump 300 is operated before the main pump 100 at a set time interval t as shown in FIG. 4. There is a deviation in the transmission time of the start control signal to the pump 100, thereby reducing the load of the main pump 100.

In addition, the controller 500 according to the embodiment of the present invention is interlocked with the tidal DB 600 as shown in FIG. 5 to control the operation of the main pump 100 and the submersible auxiliary pump 300 according to the tide information, The tide DB 600 is a database in which tide information about the water body 5 in which the sea water supply pipe 200 is installed is converted into a database. Here, the tide DB 600 according to the embodiment of the present invention includes a long-water sea level information DB unit 610 and a pumping level DB unit 620.

The water level sea level information DB unit 610 is a DB in which seasonal time-linked sea level information corresponding to the location information of the water area 5 supplying sea water to the onshore farm 2 is converted into a database as tidal tidal information, and the pumping level value DB The unit 620 is a DB in which the difference between the depth of the sea water supply pipe 200 and the sea level is converted into a database as a pumping level value.

The complex batch pump-based onshore farm seawater supply system 1 according to the embodiment of the present invention constructed as described above is installed at a depth below the minimum sea level according to the tidal ebb and flow of the water body 5 supplying seawater to the onshore farm 2 The submersible sub-pump 300 and the main pump 100 installed in the machine room 4 of the onshore farm 2 are combined on the sea water supply pipe 200, and the onshore farm 2 and the sea water supply pipe While maintaining the current facilities such as 200 as it is, the expansion of the supply seawater flow required by the scale expansion of the onshore farm 2 can be implemented through a simple installation of the submersible auxiliary pump 300. And the combined batch pump-based onshore aquaculture seawater supply system 1 according to the embodiment of the present invention is the seawater to the onshore farm 2 by increasing the flow rate and increasing the flow rate of the supplied seawater according to the additional arrangement of the submersible auxiliary pump 300. Ensure supply stability is maximized.

As described above, a composite batch pump-based onshore aquaculture seawater supply system according to an embodiment of the present invention is illustrated according to the above description and drawings, but this is only described as an example and within the scope not departing from the technical idea of the present invention. It will be well understood by those of ordinary skill in the art that various changes and changes are possible.

1: Combined batch pump-based land farm seawater supply system
2: land farm
3: water tank
4: machine room
5: water body
100: main pump
200: seawater supply pipe
210: inlet
300: submersible auxiliary pump
400: farm connection pipe
500: controller
510: land control cable
520: underwater control cable
600: Tidal DB
610: water level sea level information DB unit
620: pumping water level DB unit

Claims (5)

A main pump 100 disposed in the machine room 4 of the onshore farm 2;
A seawater supply pipe 200 connected to the main pump 100, extending below the sea level, and having an inlet 210 disposed at a set seawater inflow depth (H);
An underwater auxiliary pump 300 disposed in a submerged state below the sea level and installed in the seawater supply pipe 200 at a set pump installation depth (h) position;
A fish farm connection pipe 400 connected to the water tank 3 of the onshore farm 2 to supply seawater to the water tank 3;
A controller 500 that controls the operation of the main pump 100 and the submersible sub-pump 300 according to the tidal tidal information of the water body 5 in which the seawater supply pipe 200 is disposed; Complex batch pump-based onshore aquaculture seawater supply system characterized by. The method of claim 1,
The pump installation depth h is set to a depth value below the minimum sea level among the visually interlocked sea levels for each season corresponding to the location information of the water body 5 in which the sea water supply pipe 200 is disposed, and the submersible auxiliary pump 300 Complex batch pump-based onshore aquaculture seawater supply system, characterized in that to keep the submerged under the sea level at all times. The method of claim 1,
The controller 500 reduces the load of the main pump 100 by allowing the submersible auxiliary pump 300 to operate before the main pump 100 at a set time interval t. Batch pump based onshore aquaculture seawater supply system. The method of claim 1,
The seawater supply pipe 200 is a complex batch pump-based onshore aquaculture seawater supply system, characterized in that a portion extending below the sea level is formed in an inclined straight line. The method of claim 1,
The main pump 100,
Selected to have a pump capacity corresponding to the seawater supply flow rate (Q) required by the water tank (3) of the onshore farm (2) and the suction lift (H) based on the position of the submersible auxiliary pump (300) Made of a pump,
The submersible auxiliary pump 300,
Based on the total pump capacity required to supply the seawater supply flow rate (Q) required by the water tank 3 of the onshore farm 2 and a numerical value obtained by subtracting the pump capacity and head of the main pump 100 from the total head Complex batch pump-based onshore aquaculture seawater supply system, characterized in that consisting of a pump selected to have a large pump capacity and a small head.

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