KR20130099393A - Cooling apparatus of warm water for offshore floating body - Google Patents

Abstract

PURPOSE: A cooling apparatus of warm water for an offshore floating body is provided to store warm water discharged from an object in a cooling storage unit and cool the warm water. CONSTITUTION: A cooling apparatus of warm water for an offshore floating body comprises a ballast water storage unit (100), a cooling line (200), and a cooling storage unit (300). The ballast water storage unit has multiple ballast tanks (110) for controlling the ballast and draft of an offshore floating body by controlling the amount of ballast water. Heat-exchanged warm water for cooling an object flows in the cooling line, and the cooling line passes through one of the ballast tanks. The cooling storage unit has an inlet pipe (330), a storage tank, and an outlet pipe (340). The warm water passing through the cooling line flows into the inlet pipe. The outlet pipe discharges the warm water received in the storage tank to the outside.

Description

Cooling Apparatus of Warm Water for Offshore Floating Body}

The present invention relates to a warm water drainage cooling device discharged from the cooling target provided in the offshore fluid, using the ballast water storage unit provided in the offshore fluid coolant of the offshore fluid discharged by cooling the warm water generated from the cooling target It relates to a cooling device.

In general, seawater is mainly used as cooling water for cooling power sources generating high heat.

In particular, seawater is used for cooling when the steam from the nuclear generator is turned back into water. This seawater is discharged back to the sea by 7 ° C higher than the water intake by heat exchange with steam in the condenser, which is called warm drainage.

Since the warm drainage affects the water temperature in the surrounding seas and damages low-temperature seaweeds such as seaweed and seaweed, compensation is provided through damage investigation, but there is a conflict with fishermen about the extent of damage.

As an improvement plan, related agencies are promoting the improvement of the generator cooling method or the expansion of the use of hot water.

Developed countries have adopted strict hot-water discharge standards, but in Korea, there are no relevant emission standards and only emission standards for pollutants. In the United States, Japan, Germany, France, etc., many methods of utilizing warm drainage by using aquaculture and flowers using warm drainage have been widely used.

On the other hand, in order to supply smooth cooling water from the nuclear power generator, discharge of warm water and supply power to the island area, a method of using a nuclear power plant equipped with an offshore fluid is increasing. However, when a nuclear power generator is provided in the offshore fluid, many studies have been conducted to develop a cooling device for the discharged hot water because the utilization of the discharged hot water is not free.

In addition, various nuclear power generators are used in offshore fluids as well as nuclear power generators. The method using sea water is most widely used to cool them, and is used for cooling and discharging the hot water (sea water with elevated temperature) used for cooling the nuclear power generator. Much research is being done.

In particular, there is an environmentally friendly ship heat exchanger of Korea Patent Registration No. 10-0706046 as an example of the warm water drainage cooling device developed by the study to cool the discharged warm water.

The present invention provides an apparatus and a method for cooling off-floor fluids of off-shore fluids that can reduce the temperature rise of the sea water by the discharged warm-water drainage by cooling the warm-water wastewater by discharging it through the ballast water storage unit. Is in.

In order to solve the above problems, the warm water drainage cooling apparatus of the offshore fluid according to the present invention, the receiving space is formed therein to accommodate the ballast water and controls the balance and draft of the offshore fluid by adjusting the amount of the ballast water Ballast water storage unit having a plurality of ballast tanks (Ballast Tank), the heat-exchanged warm water for the cooling of the cooling object flows therein, and cooling through the form passing through at least one of the plurality of ballast tanks An inlet pipe into which the warm wastewater flows through the line and the cooling line, a storage tank accommodating the warm wastewater, and a discharge pipe disposed at a position lower than the inlet pipe to discharge the warm wastewater contained in the storage tank to the outside of the storage tank. It includes a cold storage comprising a.

The storage tank may further include an external exposure pipe that is partitioned into at least two and the partitioned areas communicate with each other.

In addition, the external exposure pipe is provided at a position relatively lower than the inlet pipe, it may be provided at a position relatively higher than the discharge pipe.

In addition, the external exposure pipe may be provided in plural numbers and disposed to be adjacent to each other in a lateral direction, and may be configured to exchange heat with external air.

In addition, the cooling line may be formed to be bent so that the hot water discharged to increase the contact area with the ballast in the ballast water storage.

The apparatus may further include an auxiliary cooling line connected to the cooling storage unit so as to pass through the ballast water storage unit and discharge the warm water discharged from the cooling storage unit to the outside via the ballast water storage unit. Can be.

In addition, the auxiliary cooling line may be provided to pass through the ballast tank that is not provided on the movement path of the cooling line.

In addition, the storage tank may further include a cooling fan provided therein and selectively operating to further cool the warm water supplied from the cooling line.

The warm water drainage cooling device according to the present invention has the following effects.

The cooling water discharged from the cooling target is discharged through the cooling line inside the ballast water storage unit provided in the offshore fluid containing sea water, and the warm water discharged by dropping and receiving the warm water discharged along the cooling line in the cooling storage unit. The water is cooled by the sea water stored in the ballast water storage unit at the same time there is an effect that is dropped into the cooling storage unit is cooled again.

In addition, by storing the hot water discharged from the object to be cooled for a predetermined time in the cold storage unit provided in the off-shore fluid, there is an effect that the discharged hot water is cooled.

In addition, the cold storage unit includes a temporary storage tank configured by separating at least two, and the external drain pipe is configured to be exposed to the air is connected to communicate with the hot water to move between each temporary storage tank, the external exposure pipe, There is an effect that the warm water passing through is cooled by air.

In addition, since the cooling line of the discharged hot water is formed to increase the contact area with the ballast water accommodated in the ballast water storage unit, the cooling efficiency of the discharged hot water is increased.

1 is a view schematically showing a configuration of a warm water drainage cooling apparatus of an off-shore fluid according to an embodiment of the present invention;
2 is a view showing the arrangement of the ballast water storage unit and the cooling object in the offshore fluid of FIG.
3 is a view showing the shape and the path of the cooling line of FIG.
4 is a view showing the configuration and shape of the first temporary storage tank, the second temporary storage tank and the external exposure pipe of FIG.
5 is a view showing a state in which the on-water drainage supplied from the cooling line of FIG. 4 is cooled in the cooling storage unit; And
6 is a flowchart illustrating a process of a method for cooling the waste water of the offshore fluid according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

The present invention relates to a device for cooling and discharging warm wastewater generated from a cooling object of an offshore subsided fluid. The offshore fluid in an embodiment will be described taking an example of a marine nuclear power generator.

First, a configuration according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2 as follows.

1 is a view schematically showing a configuration of a warm water drainage cooling apparatus of an offshore fluid according to an embodiment of the present invention, and FIG. 2 is a view showing the arrangement of a ballast water storage unit and a cooling target in the offshore fluid of FIG. 1.

As shown in Figure 1, in the offshore fluid (S) configuration according to an embodiment of the present invention is largely the ballast water storage unit 100, cooling line 200, cooling storage unit 300 and auxiliary It consists of a cooling line 400.

The ballast water storage unit 100 is selectively accommodated therein to maintain the horizontal and draft (depth of the part submerged in the water when the ship floats on the water) of the sea side fluid (S) by receiving the seawater therein It is configured to control the amount of seawater received.

The ballast water storage unit 100 is typically used to maintain a constant draft according to the change in the load of the floor mounted on the offshore fluid (S) and the ballast water (W1) required according to the function of the offshore fluid (S) The amount of will be different.

As such, the ballast water storage unit 100 that maintains the equilibrium and draft of the offshore fluid S is composed of a plurality of ballast tanks 110 capable of accommodating each ballast water.

The cooling line 200 is the warm water discharged from the cooling object (G) provided in the offshore fluid (S) (W2: see Figure 6) after passing through the interior of the ballast water storage unit 100, It is configured to be discharged to the cooling storage unit 300, the warm water (W2) is cooled through heat exchange with the sea water of the ballast water storage unit 100 provided on the discharge path.

Here, the warm wastewater (W2) means the seawater discharged by slightly increasing the temperature of the seawater used in the process of cooling through heat exchange to cool the object to be cooled. In this case, the cooling object may be applied in various ways and is described as the cooling object G in the present embodiment.

In this way, the cooling line 200 is the warm water (W2) discharged from the cooling object (G) via the ballast water storage unit 100 and cooled through heat exchange to the cooling storage unit 300 It is configured to be discharged.

And the cooling line 200 may be provided with a separate circulation pump 210 to smooth the flow of the warm water (W2) discharged after being used in the cooling object (G).

The cooling storage unit 300 is connected to the cooling line 200 and is disposed adjacent to the ballast water storage unit 100 to receive the warm water drainage W2 supplied from the cooling line 200 for a predetermined time. By cooling and then discharging.

Here, the cooling storage unit 300 is composed of the inlet pipe 330, the discharge pipe 340 and the storage tank (310, 320) and the inlet pipe 330 is the warm water drainage (W2) passing through the cooling line 200 Inflow. The storage tanks 310 and 320 accommodate the warm water drainage W 2, and the discharge pipe 340 discharges the warm waste water W 2 received in the storage tanks 310 and 320 to the outside of the storage tank. It is provided at a position relatively lower than the inlet pipe 330.

The cold storage unit 300 configured as described above is received in the storage tanks 310 and 320 while the warm water drainage W2 discharged from the cooling line 200 falls through the inlet pipe 330, and the storage The on-time drainage water W2 accommodated in the tanks 310 and 320 for a predetermined time is discharged to the outside of the storage tanks 310 and 320 through the discharge pipe 340 while the water level is increased.

On the other hand, the storage tank 310, 320 may be divided into a plurality of configurations, in the present embodiment is separated into the first temporary storage tank 310 and the second temporary storage tank 320, the first temporary storage tank below (310) and the second temporary storage tank.

First, the first temporary storage tank 310 accommodates the warm water drainage W2 supplied from the cooling line 200 for a predetermined time.

Here, the first temporary storage tank 310 is formed in the inlet pipe 330 in the upper side of the direction not adjacent to the second temporary storage tank 320 is connected to the cooling line 200, the cooling line ( 200 receives the warm water drainage W2 supplied. At this time, the warm water drainage (W2) is dropped into the first temporary storage tank by the drop of the bottom of the first temporary storage tank 310 and the inlet pipe 330 is cooled through the drop accordingly.

In addition, the second temporary storage tank 320 is disposed adjacent to the first temporary storage tank 310 and receives the warm water W2 received in the first temporary storage tank 310 for a predetermined time, and the auxiliary cooling is performed. Configured to discharge to line 400. In this case, the second temporary storage tank is provided with a discharge pipe 340 at a position opposite to the inlet pipe 330 and is disposed at a position relatively lower than the inlet pipe 330 to assist the warm water drainage W2. It is discharged to the cooling line 400.

Here, the storage tank further includes an external exposure pipe 350 to allow the first temporary storage tank 310 and the second temporary storage tank 320 to communicate with each other. Thus, the warm water drainage W2 received in the first temporary storage tank 310 is supplied to the second temporary storage tank 320 through the external exposure pipe 350.

The configuration of the external exposure pipe 350 will be described later with reference to FIG. 5.

On the other hand, although not shown in the drawing may be configured to further include a separate cooling fan (not shown) that can be selectively driven in the first temporary storage tank 310 and the second temporary storage tank 320. By providing the cooling fan, it is possible to increase the cooling effect of the warm water drainage (W2) supplied to the first temporary storage tank 310 and the second temporary storage tank (320).

The auxiliary cooling line 400 is connected to the cooling storage unit 300 and configured to pass through the inside of the ballast water storage unit 100 to the outside of the warm water drainage W2 received in the cooling storage unit 300 to the outside. Configured to exhaust.

Specifically, the auxiliary cooling line 400 is connected to the second temporary storage tank 320 and configured to pass through the plurality of ballast tanks 110 to discharge the warm water W2 to the outside.

In this case, the cooling line 200 and the auxiliary cooling line 400 is preferably configured to be symmetrical around the offshore fluid.

When the cooling line 200 and the sub-cooling line 400 is configured to be symmetrical, the warm water drainage (W2) is evenly passed through the plurality of ballast tanks 110 provided in the offshore fluid (S) In addition, the warm wastewater W2 may be cooled through more effective heat exchange.

Subsequently, referring to FIG. 2, the ballast water storage unit 100 includes a plurality of ballast tanks 110 in the off-shore fluid S, and each of the ballast tanks 110 has a separate control valve therein. It is configured to adjust the amount of the ballast water (W1) accommodated.

2 (a) is a view schematically showing the side of the sea floating fluid (S) and FIG. 2 (b) is a view showing the front of the sea floating fluid (S) briefly. Referring to (a) and (b) of Figure 2, the cooling object (G) is disposed in the central portion of the off-shore fluid (S) to the front and rear right and left around the cooling object (G) A plurality of the ballast tank 110 is provided in a corresponding form.

In addition, the ballast tank 110 is also disposed in the lower portion of the marine fluid (S) is configured to face the center of gravity down.

As such, the offshore fluid S is typically provided with a plurality of ballast tanks 110 configured to accommodate the ballast water W1 to adjust the amount of the ballast water W1 accommodated therein. And to maintain the equilibrium and draft of S).

Next, the path and shape of the cooling line 200 and the auxiliary cooling line 400 will be described with reference to FIG. 3.

3 is a view showing the shape and the path of the cooling line 200 of FIG.

As shown, the cooling line 200 is one side is connected to the first temporary storage tank 310 and configured to pass through the plurality of ballast tanks 110, is discharged from the cooling object (G) The warm water drainage W2 is cooled by heat exchange with the ballast water W1 accommodated in the ballast tank 110.

At this time, the cooling line 200 is formed spirally so as to increase the area in which the on-water drainage (W2) moved inside the contact with the ballast water (W1) accommodated in the ballast tank (110).

Since the cooling line 200 is formed spirally, the contact area with the ballast water W1 accommodated in the ballast tank 110 increases to increase the contact area with the warm water W2 and the inside of the cooling line 200. The heat exchange between the ballast water (W1) to occur a lot.

In addition, the auxiliary cooling line 400 may be formed in the same manner as the cooling line 200.

The auxiliary cooling line 400 is configured such that one side is connected to the second temporary storage tank 320 and the other side is connected to the outside and passes through the plurality of ballast tanks 110.

Thus, similar to the cooling line 200, the warm wastewater W2 discharged from the second temporary storage tank 320 is cooled by heat exchange with the ballast water W1 accommodated in the ballast tank 110.

In addition, the auxiliary cooling line 400 is also provided with a circulation pump 410 for smoothly flowing the warm water (W2), which is moved in the same manner as the cooling line (200).

In the present embodiment, the shape of the auxiliary cooling line 400 and the cooling line 200 has been described in a spiral form, but this is not limited to a specific form. By increasing the contact area of the warm water (W2) and the ballast water (W1) accommodated in the ballast water storage unit 100 moving in the auxiliary cooling line 400 and the cooling line 200, Any configuration may be used as long as the configuration allows heat exchange to occur.

Next, a configuration of the cooling storage unit 300 will be described with reference to FIGS. 4 and 5.

4 is a view showing the configuration and shape of the first temporary storage tank 310, the second temporary storage tank 320 and the external exposure pipe 350 of Figure 1 and Figure 5 is from the cooling line 200 of FIG. The on-time drainage water W2 supplied is a view showing a state in which the cooling storage unit 300 is cooled.

First, as shown in FIG. 4, the cold storage unit 300 includes the first temporary storage tank 310, the second temporary storage tank 320, the inlet pipe 330, and the discharge pipe 340. And the external exposure pipe 350, and each of the first temporary storage tank 310 and the second temporary storage tank 320 is disposed adjacent to the plurality of ballast tanks 110.

And the inlet pipe 330 is provided on one side of the first temporary storage tank 310 is connected to the cooling line 200, the on-water drainage (W2) discharged along the cooling line 200 Supply to the first temporary storage tank (310). The discharge pipe 340 is provided in a direction opposite to the inflow pipe 330 in the second temporary storage tank 320 and is disposed at a position relatively lower than the inflow pipe 330 to store the second temporary storage tank 340. The warm wastewater (W2) accommodated in the tank 320 is discharged to the auxiliary cooling line (400).

On the other hand, the external exposure pipe 350 is disposed so as to communicate with each other between the first temporary storage tank 310 and the second temporary storage tank 320 and a plurality of along the transverse direction of the first temporary storage tank The warm water drainage W2 accommodated in the 310 may move to the second temporary storage tank 320.

Here, the external exposure pipe 350 has one side connected to the first temporary storage tank 310, the other side is connected to the second temporary storage tank 320, and an intermediate portion thereof is connected to the first temporary storage tank 310. It is provided to be located in a separate communication space 360 formed between the second temporary storage tank 320. .

The communication space 360 is formed to allow external air to pass through such that the external exposure pipe 350 contacts external air. The external exposure pipe 350 is configured to be in contact with the outside air, so that the warm water drainage (W2) moving from the first temporary storage tank 310 to the second temporary storage tank 320 is the external exposure pipe ( When moving through 350, it is cooled through heat exchange in contact with external air.

The cooling storage unit 300 configured as described above accommodates and cools the warm water drainage W2 supplied from the cooling line 200 in the first temporary storage tank 310 and the first temporary storage tank 310. Cooling once again through contact with air while the warm water (W2) accommodated in the) through the external exposure pipe 350.

In addition, the warm wastewater W2 is accommodated in the second temporary storage tank 310 and cooled. Here, by operating the cooling fan provided in the first temporary storage tank 310 and the second temporary storage tank 320, it is possible to further increase the cooling effect of the warm water (W2).

Referring to FIG. 5, the cooling line 200 is connected to an upper portion of the first temporary storage tank 310 to supply the warm water drainage W2 via the ballast tank 110 to the first temporary storage tank 310. To supply.

The first temporary storage tank 310 accommodates the predetermined amount of the warm water (W2), the warm water (W2) through heat exchange with the ballast water (W1) accommodated in the plurality of adjacent ballast tanks (110) disposed Cool down.

In addition, the warm water drainage (W2) supplied from the inlet pipe 330 provided on the first temporary storage tank 310 falls into the first temporary storage tank 310 while performing heat exchange through contact with air. Is cooled.

In addition, when the first temporary storage tank 310 rises above a predetermined level by the continuous supply of the warm water (W2) from the cooling line (200), the warm water (W2) is along the outer exposure pipe (350). The second temporary storage tank 320 is moved. Here, too, the warm wastewater W2 is cooled through heat exchange with air while falling into the second temporary storage tank 320.

In this case, the external exposure pipe 350 is disposed at a relatively lower position than the inlet pipe 330 and is preferably disposed at a relatively higher position than the discharge pipe 340.

On the other hand, the warm water (W2) is moved through the external exposure pipe 350 when moving from the first temporary storage tank 310 to the second temporary storage tank 320, the external exposure pipe 350 is The first temporary storage tank 310 and the second temporary storage tank 320 are provided to communicate with each other so that the on-going drainage water W2 is in contact with the outside air. Thus, the warm water drainage W2 is moved along the outer exposure pipe 350 so as to be heat-exchanged through contact with the outside air and cooled.

As such, the warm water drainage W2 cooled while passing through the external exposure pipe 350 from the first temporary storage tank 310 is supplied to the second temporary storage tank 320.

The second temporary storage tank 320 accommodates the warm water drainage (W2) therein for a predetermined time, and when the warm water drainage (W2) accommodated above a certain level rises, the warm water drainage (W2) is transferred to the auxiliary cooling line ( 400).

Subsequently, referring to FIG. 6, the cooling process of the warm water drainage W2 of the offshore fluid S according to an embodiment of the present invention is as follows.

FIG. 6 is a flowchart illustrating a process according to the method for cooling the warm water W2 of an offshore fluid S according to an embodiment of the present invention.

First, discharging the warm water (W2) used for cooling the steam used in the cooling target (G) (S01). In addition, the warm wastewater W2 discharged from the cooling target G is moved through the interior of the plurality of ballast tanks 110 along the cooling line 200 (S02).

The warm drainage water W2 is first cooled through heat exchange with the ballast water W1 accommodated in the ballast tank 110 (S03).

In addition, the warm drainage water W2 via the ballast tank 110 is supplied to the first temporary storage tank 310 and received (S04). The warm water drainage W2 accommodated in the first temporary storage tank 310 is accommodated for a predetermined time and secondarily cooled (S05).

Thereafter, the warm water drainage W2 accommodated in the first temporary storage tank 310 passes through the external exposure pipe 350 (S06), and the warm water drainage W2 passes through the external exposure pipe 350. By being in contact with the air is cooled in the third through heat exchange (S07).

Here, although not shown in the drawing, by selectively operating the cooling fan provided in the first temporary storage tank 310 and the second temporary storage tank 320 to increase the cooling effect of the warm water drainage (W2). Can be.

The warm drainage water W2 passing through the external exposure pipe 350 is accommodated in the second temporary storage tank 320 (S08) and the warm drainage water W2 received in the second temporary storage tank 320 is the auxiliary. It is discharged back to the cooling line (400). Here, the auxiliary cooling line 400 is configured to pass through the interior of the plurality of ballast tank (110). (S09)

The warm water drainage W2 moving along the auxiliary cooling line 400 is cooled in the fourth order through heat exchange with the ballast water W1 in the ballast tank 110 (S10).

Finally, the on-line drainage water W2 cooled to the fourth through the auxiliary cooling line 400 is discharged to the outside (S11).

The warm wastewater (W2) discharged from the cooling target (G) while going through this process is cooled through four stages of cooling and discharged to the outside.

It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is obvious to them. Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: ballast water storage unit 110: ballast tank
200: cooling line 210, 410: circulation pump
300: cold storage unit 310: the first temporary storage tank
320: second temporary storage tank 330: inlet pipe
340: discharge pipe 350: external exposure pipe
360: communication space 400: auxiliary cooling line

Claims (8)

A ballast water storage unit having a ballast tank configured to accommodate ballast water therein and having a plurality of ballast tanks controlling the balance and draft of the offshore fluid by adjusting the amount of ballast water;
A cooling line through which the heat-exchanged warm / exhaust water flows for cooling the object to be cooled, and passes through the inside of at least one of the plurality of ballast tanks; And
An inlet pipe through which the warm drainage flows through the cooling line, a storage tank for accommodating the warm wastewater, and a discharge pipe disposed at a position lower than the inlet pipe to discharge the warm wastewater received in the storage tank to the outside of the storage tank; Cooling storage unit;
Warm water drainage device of the offshore fluid comprising a. The method of claim 1,
Wherein the storage tank comprises:
And at least two external exposure pipes which are partitioned into at least two and allow the partitioned areas to communicate with each other. The method of claim 2,
The outer exposure pipe,
It is provided at a position relatively lower than the inlet pipe, the on-water drainage cooling device of the offshore fluid is provided at a position relatively higher than the discharge pipe. The method of claim 2,
The outer exposure pipe,
A warm water drainage cooling apparatus for offshore sub-liquids provided in plural numbers and arranged adjacently in a lateral direction to exchange heat by contacting outside air. The method of claim 1,
The cooling line may include:
Apparatus for cooling the hot water of the offshore side fluid is discharged to be formed so as to increase the contact area with the ballast in the ballast water storage. The method of claim 1,
It is connected to the cold storage unit is provided to pass through the inside of the ballast water storage portion, the offshore portion further comprises a secondary cooling line for discharging the hot water discharged from the cold storage portion via the inside of the ballast water storage portion to the outside Cooling water chiller of fluid. The method according to claim 6,
The auxiliary cooling line,
On-water drainage cooling device of the offshore fluid is provided to pass through the ballast tank not provided on the movement path of the cooling line. 8. The method according to any one of claims 1 to 7,
Wherein the storage tank comprises:
And a cooling fan provided therein and selectively operating to cool the warm water further supplied from the cooling line.

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