KR102186631B1 - Seawater treatment system having high temperature reduction function - Google Patents

Abstract

The present invention relates to a seawater treatment system having a high water temperature reduction function, and more particularly, by reducing the temperature of high-temperature seawater by a high-water temperature reduction device, low-temperature seawater is supplied to the seawater area inside the cage farm, and in particular, the low-temperature seawater cage farm It relates to a seawater treatment system having a function of reducing high water temperature so that a cold water layer is formed by being continuously discharged in accordance with the flow direction of seawater passing through the interior.
According to the features of the present invention for achieving the above object, the present invention is installed in a high-temperature seawater inlet pipe through which high-temperature seawater is introduced and a barge located at the sea level at the edge of a cage farm, and the high temperature introduced through the high-temperature seawater inlet pipe. A high water temperature reduction device that generates low-temperature seawater with reduced temperature by exchanging seawater with a heat medium and low-temperature seawater are discharged to the inside of the cage farm, but the low temperature seawater is discharged in a direction aligned with the flow direction of the seawater passing through the inside of the cage farm. It characterized in that it comprises a; low-temperature seawater discharge pipe.

Description

Seawater treatment system having high temperature reduction function}

The present invention relates to a seawater treatment system having a high water temperature reduction function, and more particularly, by reducing the temperature of high-temperature seawater by a high-water temperature reduction device, low-temperature seawater is supplied to the seawater area inside the cage farm, and in particular, the low-temperature seawater cage farm The present invention relates to a seawater treatment system having a function of reducing high water temperature to sterilize and purify harmful red tide by continuously discharging it in accordance with the flow direction of seawater passing through the interior.

In aquaculture for raising fish and shellfish, there are a cage type, a static type, a flow type, and a land tank type, depending on the method of supplying the breeding water. Of these, so far, offshore cage farming is the largest and the supply of farmed fish also accounts for a large proportion. In the cage farming, a mesh of a certain size is installed in rivers and seas, and dissolved oxygen and salts present in a large amount of natural water are continuously used, and feed debris and excreta of aquaculture organisms generated during the farming process are introduced into natural water. It is a way that is naturally purified. Fish and shellfish farmed mainly in the offshore are cultivated in cage farming, and a large amount of seawater is used.

The phenomenon of extinction or change of dominant fish species in cage farms and oceans is accelerating due to the increase in sea level or surface water temperature due to warming. In particular, it has been known that the scale of damage to the cage farm due to the increase in seawater temperature is quite large.

Republic of Korea Public Utility Model Publication No. 20-2014-0002636 "Sea water cooler for marine farms" is to improve this problem, reducing the temperature by several degrees in a certain area around the cooler to reduce the damage caused by the increase in sea water temperature. It is characterized by minimizing.

However, the prior art is a structure that cools the seawater by installing a cooler in the water, so installation and separation of the device is cumbersome, and the temperature of the seawater in the farm is not maintained as the temperature is temporarily reduced only around the cooler regardless of the flow of seawater. There was this.

Republic of Korea Public Utility Model Publication No. 20-2014-0002636

The present invention was conceived to solve the above problems, and the low-temperature seawater whose temperature has been reduced by a high water temperature reduction device is continuously discharged in accordance with the flow direction of the seawater passing through the inside of the cage farm to form a cold water layer. It is an object of the present invention to provide a seawater treatment system having a high water temperature reduction function.

In addition, it is an object of the purpose of allowing the liquefied oxygen to be discharged together with the low-temperature seawater to form a lower-temperature seawater cold water layer.

In addition, it aims to purify seawater by removing suspended matter or pollutants around the cage farm.

In addition, when red tide occurs, the purpose is to disinfect and purify the harmful red tide of high temperature seawater by placing it in the flow direction of seawater flowing into the cage farm to be supplied to the cage farm.

According to the features of the present invention for achieving the above object, the present invention is installed in a high-temperature seawater inlet pipe through which high-temperature seawater is introduced and a barge located at the sea level at the edge of a cage farm, and the high temperature introduced through the high-temperature seawater inlet pipe. A high-water temperature reduction device that generates low-temperature seawater with reduced temperature by exchanging seawater with a heat medium, and low-temperature seawater are discharged into the cage, but the low-temperature seawater continues in a direction aligned with the flow direction of the seawater passing through the cage. It is characterized by including a low-temperature seawater discharge pipe that is discharged to form a cold water layer in the cage farm.

In addition, the high water temperature reduction device is a seawater pump that raises seawater to the barge, a seawater filter that filters seawater introduced by the seawater pump, and a seawater filter that is connected to the seawater filter to heat exchange between the filtered seawater and a heat medium to reduce seawater temperature. Including a cooler, wherein the cooler is connected to the cooler body in which the heat medium is accommodated and the seawater filter outside the cooler body, and is connected to the cooler inlet pipe and the cooler inlet pipe into which seawater flows into the cooler body. A cooler seawater pipe in which a flowing pipe is formed, a cooler discharge pipe connected to the cooler seawater pipe to discharge seawater to the outside of the cooler body, and a liquefied oxygen tank connected to the cooler discharge pipe to supply liquefied oxygen, and the cooler discharge pipe The seawater discharged through is discharged together with liquefied oxygen to further reduce the seawater temperature.

In addition, it is installed on the barge, and further includes a red tide treatment device that sterilizes and purifies the harmful red tide of seawater, and when a red tide occurs, a barge is disposed in the flow direction of the seawater flowing into the cage farm by moving to the red tide area. It is characterized in that the seawater sterilized and purified by is supplied to the cage farm.

As described above, according to the present invention, a cold water layer is formed by continuously discharging low temperature seawater whose temperature has been reduced by a high water temperature reduction device, so that fish in the farm can stay in the cold water layer and survive safely avoiding high water temperatures. The high water temperature has the advantage of minimizing damage.

In addition, there is an advantage of helping to purify seawater by removing suspended matter and pollutants from seawater.

In addition, since it is installed on a barge located at sea level, it is easy to install, separate, and move the device.

In addition, low-temperature seawater is provided so as to be discharged in accordance with the flow direction of seawater in the aquaculture, so that the temperature of seawater can be efficiently reduced.

In addition, there is an advantage of disinfecting and purifying the harmful red tide of high temperature seawater by disposing it in the flow direction of seawater flowing into the cage farm when a red tide occurs and supplying it to the cage farm.

1 is a conceptual diagram of a seawater treatment system having a high water temperature reduction function according to the present invention.
2 is a block diagram of an apparatus for providing temperature information of a seawater treatment system having a function of reducing high water temperature according to the present invention.
3 is a block diagram of a high water temperature reduction apparatus of a seawater treatment system having a high water temperature reduction function according to the present invention.
4 is a block diagram of a cooler of a seawater treatment system having a function of reducing high water temperature according to the present invention.
5 is an embodiment showing a case where the flow of seawater flows from left to right in the seawater treatment system having a high water temperature reduction function according to the present invention.
6 is another embodiment showing a case where the flow of seawater flows from right to left in the seawater treatment system having a high water temperature reduction function according to the present invention.
Figure 7 is another embodiment showing a state in which the seawater treatment system having a high water temperature reduction function according to the present invention is installed in a circular cage farm.
8 is a conceptual diagram of a red tide treatment device installed in a seawater treatment system having a high water temperature reduction function according to the present invention.
9 is an embodiment showing an operating state in which a red tide treatment device is installed in a seawater treatment system having a high water temperature reduction function according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted in order to clarify the gist of the present invention.

In addition, in describing the present invention, terms indicating a direction are described so that those skilled in the art can clearly understand the present invention, and indicate a relative direction, and thus the scope of the rights is not limited.

1 is a conceptual diagram of a seawater treatment system having a high water temperature reduction function according to the present invention, FIG. 2 is a block diagram of an apparatus for providing temperature information of a seawater treatment system having a high water temperature reduction function according to the present invention, and FIG. 3 is the present invention It is a configuration diagram of a high water temperature reduction apparatus of a seawater treatment system having a high water temperature reduction function according to, and FIG. 4 is a configuration diagram of a cooler of a seawater treatment system having a high water temperature reduction function according to the present invention.

And Figure 5 is an embodiment showing a case where the flow of seawater flows from left to right in the seawater treatment system having a high water temperature reduction function according to the present invention, Figure 6 is a seawater treatment system having a high water temperature reduction function according to the present invention Another embodiment showing a case where the flow of seawater flows from right to left, and FIG. 7 is another embodiment showing a state in which the seawater treatment system having a high water temperature reduction function according to the present invention is installed in a circular cage farm.

And Figure 8 is a conceptual diagram of a red tide treatment device is installed in the seawater treatment system having a high water temperature reduction function according to the present invention, Figure 9 is a red tide treatment device is installed in the seawater treatment system having a high water temperature reduction function according to the present invention to show the operating state. It is an example shown.

1 to 4, a seawater treatment system having a high water temperature reduction function according to an embodiment of the present invention is a system for reducing the temperature of seawater in a cage farm, and a high-temperature seawater inlet pipe 100, a high water temperature reduction device 200, It consists of a low-temperature seawater discharge pipe 300, a temperature information providing device 400, an opening and closing control device 500, an inlet pipe opening and closing device 600, and a red tide treatment device 700, and each configuration will be described below.

The high-temperature seawater inlet pipe 100 is disposed on the sea level or surface water whose water temperature has risen due to warming, and the high-temperature seawater A of the sea surface or surface water is introduced through the pipe.

The high water temperature reduction device 200 is disposed at the edge of the cage farm 1 and is installed on the barge 10 located at the sea level. In addition, the high water temperature reduction device 200 heats the high-temperature seawater (A) introduced through the high-temperature seawater inlet pipe 100 with a heat medium to generate low-temperature seawater (B) having a reduced temperature.

The high water temperature reduction device 200 is composed of a seawater pump 210, a seawater filter 220, and a cooler 230, as shown in FIG. 3, and each configuration will be described in detail below.

The seawater pump 210 is connected to the high-temperature seawater inlet pipe 100 to raise sea level or surface water to the top of the barge 10 and supply it to the seawater filter 220 to be described later.

The seawater filter 220 purifies the seawater by filtering suspended matter or pollutants of seawater introduced by the seawater pump 210.

The cooler 230 is connected to the seawater filter 220 and reduces the seawater temperature by heat exchange between the filtered high-temperature seawater A and the heat medium. The cooler 230 is connected to the cooler body 231 in which the heat medium is accommodated and the seawater filter 220 outside the cooler body 231 to flow in the sea water, and the cooler inlet pipe 232 and the cooler inlet pipe 232 The cooler seawater pipe 233 and the cooler seawater pipe 233 connected to the cooler body 231 to form a conduit through which seawater flows inside the cooler body 231 and the cooler discharge pipe 234 through which seawater is discharged to the outside of the cooler body 231 And a liquefied oxygen tank 235 connected to the cooler discharge pipe 234 to supply liquefied oxygen, and the low temperature seawater (B) discharged through the cooler discharge pipe 234 is discharged together with the liquefied oxygen to further increase the temperature of the seawater. Reduce. In addition, the cooler seawater pipe 233 is composed of a plurality of vertical pipes 233a that are spaced apart from each other in parallel and a horizontal pipe 233b that is alternately arranged vertically and connects the vertical pipes 233a adjacent to each other. ) It is formed to increase the heat exchange area within.

The low-temperature seawater discharge pipe 300 is provided so that the low-temperature seawater (B) is discharged into the cage farm (1). In addition, low-temperature seawater (B) is discharged in a direction aligned with the flow direction of seawater passing through the inside of the cage farm (1), so that the temperature of the seawater inside the cage farm (1) can be efficiently reduced. The low-temperature seawater discharge pipe 300 is located underwater and is installed so that its end is inclined upward, so that the reduced temperature seawater may be discharged to a long distance while drawing a parabolic line.

Referring to FIG. 2, the temperature information providing device 400 provides seawater temperature information, and includes a temperature measuring sensor 410 and a sea condition information providing server 420. The temperature measurement sensor 410 is preferably installed at the sea level, and the information is collected by the maritime status information providing server 420 through a device such as an artificial satellite, or the maritime status information providing server 420 of the Meteorological Agency. .

The opening/closing controller 500 controls the seawater temperature information provided by the temperature information providing device 400 to flow into the seawater when it reaches a set temperature, and controls the inflow of seawater to be blocked when the temperature is less than the set temperature.

The inlet pipe opening and closing device 600 opens and closes the high-temperature seawater inlet pipe 100 by the opening and closing controller 500, and is preferably provided at the front end of the high-temperature seawater inlet pipe 100. The inlet pipe opening/closing device 600 is made up of various openings such as a flange and a blind valve, and is opened and closed by the opening/closing controller 500.

8 and 9, the red tide treatment device 700 is installed on the barge 1 and is a device that sterilizes and purifies harmful red tide and supplies oxygen. The red tide treatment apparatus 700 is provided with a red tide seawater inlet 710 and a sterilization and purification seawater outlet 720 to introduce red tide seawater, sterilize harmful red tide through a five-step sterilization and purification process, and spray it into the seawater. That is, when a red tide occurs, the barge 1 is placed in the flow direction of the seawater inflow of the cage 1 by moving to the red tide area so that red tide seawater does not flow into the cage 1, and sterilized by the red tide treatment device 700 And after purification, sterilized and purified seawater is supplied to the cage farm (1), and the harmful red tide layer is destroyed.

More specifically, the red tide treatment apparatus 700 includes a 100 micron SUS mesh filter that filters bacterial spores of 100 microns or more, a 50 micron SUS mesh filter that filters bacterial spores of 50 microns or more, a medium pressure lamp or an amalgam sterilization lamp. The first UV lamp for blow treatment, a heating coil tank that sterilizes the bacteria that come into contact by passing through a heating coil to sterilize by a heating method, a cooling tank that prevents bacterial activation by sterilizing temperature-sensitive bacteria through a heat exchange method, titanium plate and platinum coating Plasma to sterilize bacteria, medium pressure lamp or amalgam sterilization lamp by a second ultraviolet lamp for final sterilization and sterilization of bacteria, and a 10 micron filter to filter out bacteria and suspended matters of 10 microns or more.

The seawater treatment system having such a high water temperature reduction function may be provided on both sides of the seawater inflow and outflow direction of the cage farm 1, and may be provided at any one selected from the upper and lower sides, or both upper and lower sides. At this time, ocean current detection sensors (not shown) that detect the flow direction of seawater are provided on both sides of the cage farm (1), and the plate attached to the ocean current detection sensor moves in the flow direction of the ocean current according to the flow of the ocean, and the sensor operates. do. In addition, it is possible to increase efficiency by controlling the operation of the seawater treatment system having a high water temperature reduction function according to the change of the current detected by the ocean current sensor.

In addition, a plurality of pipes are connected to the cage farm (1), and a cold water pipe through which cold water flows is fixedly installed. At this time, the cold water pipe is fixedly installed on both sides of the cage farm 1 and in any one selected from the upper or lower side, or fixedly installed on both the upper and lower sides. In addition, the cold water pipe is docked with a coupling with a low-temperature seawater discharge pipe of a seawater treatment system having a high water temperature reduction function, so that it is easy to separate and combine, and the seawater treatment system having a high water temperature reduction function can be freely moved due to this coupling combination.

As shown in FIG. 5, an embodiment of a seawater treatment system having a high water temperature reduction function will be described in which the flow of seawater flows from left to right.

First, the cage farm 1 is divided into a plurality of zones 1a, and each zone 1a is formed in a square shape.

At this time, the high-temperature seawater (A) from the surface water near the Gaduri farm (1) is pulled up through the high-temperature seawater inlet pipe (100).

And while the high water temperature reduction device 200 installed on the upper part of the barge 10 is provided on both sides of the seawater inflow and outflow direction of the cage farm 1, it may be provided at any one selected from the upper and lower sides, or both upper and lower sides. .

The low-temperature seawater discharge pipe 300 connected to the high water temperature reduction device 200 is provided connected to a plurality of zones (1a) forming the cage farm (1), and is disposed in the middle water of the cage farm (1) to provide low-temperature seawater (B). Discharge continuously.

Here, when the flow of seawater flows from left to right as shown in FIG. 5, the flow of seawater is operated by operating the direction of the seawater inflow (left) of the cage farm (1) and the high water temperature reduction device 200 provided at the upper side. The reduced seawater in the direction allows efficient diffusion.

That is, an artificial cold water layer is formed through the continuous discharge of the low temperature seawater (B), so that the fish of the high temperature seawater (A) naturally move to the cold water layer, thereby reducing the mortality of fish due to the high temperature.

In addition, when a red tide occurs, a barge equipped with a red tide treatment device is moved and arranged in the direction (left) where seawater flows into the cage farm (1), and after sterilizing and purifying the red tide seawater, it is supplied to the cage farm (1) with oxygen to cause harmful effects. It breaks the red tide layer.

As shown in FIG. 6, another embodiment showing a case where the flow of seawater in the seawater treatment system having a high water temperature reduction function flows from right to left will be described.

First, the cage farm 1 is divided into a plurality of zones 1a, and each zone 1a is formed in a square shape.

At this time, the high-temperature seawater (A) from the surface water near the Gaduri farm (1) is pulled up through the high-temperature seawater inlet pipe (100).

And while the high water temperature reduction device 200 installed on the upper part of the barge 10 is provided on both sides of the seawater inflow and outflow direction of the cage farm 1, it may be provided at any one selected from the upper and lower sides, or both upper and lower sides. .

The low-temperature seawater discharge pipe 300 connected to the high water temperature reduction device 200 is provided connected to a plurality of zones (1a) forming the cage farm (1), and is disposed in the middle water of the cage farm (1), so that low-temperature seawater (B) Discharge continuously.

Here, when the flow of seawater flows from right to left as shown in FIG. 6, the flow of seawater is operated by operating the direction (right) in which seawater flows in the cage farm (1) and the high water temperature reduction device 200 provided at the upper side. The reduced seawater in the direction allows efficient diffusion.

That is, an artificial cold water layer is formed through the continuous discharge of the low temperature seawater (B), so that the fish of the high temperature seawater (A) naturally move to the cold water layer, thereby reducing the mortality of fish due to the high temperature.

In addition, when a red tide occurs, a barge equipped with a red tide treatment device is moved and arranged in the direction (right) where seawater flows into the cage farm (1), and after sterilizing and purifying the red tide seawater, it is supplied to the cage farm (1) with oxygen to cause harmful effects. It breaks the red tide layer.

As shown in FIG. 7, another embodiment showing a state in which a seawater treatment system having a high water temperature reduction function according to the present invention is installed in a circular cage farm will be described.

First, the cage farm (1) is formed in a circular shape.

At this time, the high-temperature seawater (A) from the surface water near the Gaduri farm (1) is pulled up through the high-temperature seawater inlet pipe (100).

And the high water temperature reduction device 200 installed on the upper portion of the barge 10 is provided on both sides of the cage farm 1 in the seawater inflow and outflow direction.

And the low temperature seawater discharge pipe 300 connected to the high water temperature reduction device 200 is connected to the inside of the cage farm 1, and is disposed in the middle water of the cage farm 1 to continuously discharge low temperature seawater B.

Through the continuous discharge of the low-temperature seawater (B), an artificial cold water layer is formed so that fish in the high-temperature seawater (A) naturally move to the cold water layer, thereby reducing the mortality of fish due to the high temperature.

In addition, when a red tide occurs, a barge equipped with a red tide treatment device is moved and arranged in the direction of the seawater inflow from the cage farm (1), and after sterilizing and purifying the red tide seawater, it is supplied to the cage farm (1) with oxygen to provide the harmful red tide layer. Break up

As described above, the basic technical idea of the present invention is to reduce the temperature of high-temperature seawater by means of a high-water temperature reduction device, so that low-temperature seawater is supplied to the seawater area inside the cage farm, and in particular, the flow direction of the seawater passing through the inside of the cage farm It can be seen that it is to provide a seawater treatment system having a function of reducing high water temperature to sterilize and purify harmful red tide by continuously discharging it to form a cold water layer.

Within the scope of the basic technical idea of the present invention, various modifications can be made by those with ordinary knowledge in the art, and therefore, the scope of the present invention should be interpreted within the scope of the claims written to include various modifications. will be.

A: high temperature seawater
B: low temperature seawater
1: cage farm
1a: zone
10: barge
100: high temperature seawater inlet pipe
200: High water temperature reduction device
210: seawater pump
220: seawater filter
230: cooler
231: cooler body
232: cooler inlet pipe
233: cooler seawater pipe
233a: vertical tube
233b: horizontal tube
234: cooler discharge pipe
235: liquefied oxygen tank
300: low temperature seawater discharge pipe
400: temperature information providing device
410: temperature measurement sensor
420: sea condition information providing server
500: opening and closing control device
600: inlet pipe opening and closing device
700: red tide treatment device
710: red tide seawater inlet
720: sterilization and purification seawater outlet

Claims (3)

A high-temperature seawater inlet pipe through which hot seawater is introduced;
A high water temperature reduction device installed on a barge located on the sea level at the edge of the cage farm, and heat-exchanging the high-temperature seawater introduced through the high-temperature seawater inlet pipe with a heat medium to generate low-temperature seawater with a reduced temperature;
Low-temperature seawater is discharged into the cage farm, but the low-temperature seawater is continuously discharged in a direction aligned with the flow direction of the seawater passing through the cage farm to form a cold water layer in the cage farm. A low-temperature seawater discharge pipe installed to be inclined in a direction and discharged to a long distance while drawing a parabolic line of temperature-reduced seawater;
An ocean current detection sensor provided on both sides of the cage farm, and the attached plate is moved in the flow direction of ocean current to detect the flow direction of seawater; Including,
The high water temperature reduction device,
A seawater pump that raises seawater to the barge;
A seawater filter for filtering seawater introduced by the seawater pump;
Including; a cooler connected to the seawater filter and heat-exchanging the filtered seawater and the heat medium to reduce the seawater temperature,
The cooler,
A cooler body in which the heat medium is accommodated;
A cooler inlet pipe connected to the seawater filter outside the cooler body to introduce seawater;
A cooler consisting of a horizontal pipe that is connected to the cooler inlet pipe to form a pipe through which seawater flows inside the cooler body, and a plurality of vertical pipes spaced apart from each other and a horizontal pipe alternately arranged vertically by connecting vertical pipes adjacent to each other Seawater pipe;
A cooler discharge pipe connected to the cooler seawater pipe to discharge seawater to the outside of the cooler body;
Includes; a liquefied oxygen tank connected to the cooler discharge pipe to supply liquefied oxygen,
A red tide treatment device installed on the barge and sterilizing and purifying harmful red tide of seawater; further comprising,
When a red tide occurs, a barge is placed in the direction of the flow of seawater flowing to the red tide area and flowing into the cage farm, and the seawater sterilized and purified by the red tide treatment device is supplied to the cage farm, and the seawater discharged through the cooler discharge pipe is liquefied. Seawater treatment system having a high water temperature reduction function, characterized in that the seawater temperature is further reduced by being released together with oxygen.

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