KR20160015875A - Seawater Discharging System And Method - Google Patents

Abstract

A sea water discharging system and a sea water discharging method are disclosed. According to the present invention, the sea water discharging system provided to an offshore plant comprises: a sea water cooling line provided to the offshore plant and supplying sea water to a cooling source to be discharged; a sea water heating line provided to the offshore plant and supplying the sea water to a heating source to be discharged; and a mixing line connecting the sea water cooling line and the sea water heating line. Therefore, the present invention mixes the high-temperature sea water discharged after being supplied to the cooling source and the low-temperature sea water discharged after being supplied to the heating source to be discharged to the outside of the offshore plant.

Description

Seawater Discharging System And Method

The present invention relates to a seawater discharge system and method, and more particularly, to a seawater discharge system and method for supplying and discharging seawater as a cooling heat source, a seawater heating line for supplying and discharging seawater as a heat source for heating, The present invention relates to a seawater discharge system and method capable of mixing high temperature seawater supplied after being supplied with a cooling heat source and low temperature seawater supplied after being supplied to a heating source and discharged to the outside of the offshore plant will be.

Recently, as the environmental regulations have been strengthened, the construction of a combined-cycle power plant with a high performance and reliability with a low emission of pollution compared to coal-fired power and nuclear power generation (apparatus) is rapidly increasing.

Such a combined-cycle power plant (device) basically consists of a gas turbine, a heat recovery steam generator, and a steam turbine. In order to increase the efficiency of the system, the combined-cycle power plant generates electricity by rotating the gas turbine with the high-temperature combustion gas generated by burning the fossil fuel, and then the high-temperature combustion gas discharged from the gas turbine Gas) to produce steam from the batch recovery boiler, which in turn produces a secondary power by turning the steam turbine.

Generally, a power plant having such a combined-cycle power generation facility or a power generation facility to produce electricity has been conventionally installed on the land, especially on a coastal area where the supply and demand of raw materials is easy and the cost of securing the paper is low.

In recent years, however, it has become more and more common for ships and marine structures to be able to develop power plants in a convenient place for supply and demand, Technologies are being developed to mount the plant.

For example, a power plant is installed on a floating ocean platform, such as a barge, to supply necessary electricity from the offshore structure itself, or to generate electricity on the sea and transmit it over the land.

The combined-cycle power plant generates steam by supplying the sequential recovery boiler with the high-temperature combustion gas (exhaust gas) discharged from the gas turbine, turns the steam turbine to generate secondary power, drives the steam turbine The exhaust steam that is exhausted is again supplied to the batch recovery boiler. Such a plurality of processes requires a large amount of cooling water input, and seawater can be used as such cooling water.

In addition, seawater can be used as a heat source for gasification of liquefied natural gas, when the liquefied natural gas is vaporized in a marine plant and used as power generation fuel in the ship or on the land.

FIG. 1 schematically shows an example of an offshore plant in which seawater is taken as described above and used as a heat source for heating and cooling in the ship and then discharged.

1, when seawater is used as cooling water or a heat source for heating, seawater is taken and stored in storage tanks 10 and 20 and supplied to apparatuses such as heat exchanger 11 and vaporizer 21 Respectively, to the outside of the hull.

However, when the seawater is discharged, the seawater is used as the cooling water and used as the heated seawater and the heat source, and the cooled seawater has a large temperature difference from the surface seawater of the surrounding seawater and can cause environmental pollution and have a serious effect on the marine ecosystem . There is also a risk that the seawater discharged along the direction of the algae may be reabsorbed into the inlet.

The present invention is to solve such a problem and propose a seawater discharge system which minimizes the temperature difference with the surface water of the surrounding sea and does not have a risk of re-suction of the discharged seawater.

According to an aspect of the present invention, in a seawater discharge system provided in an offshore plant,

A seawater cooling line provided in the offshore plant for supplying and discharging seawater as a cooling heat source;

A seawater heating line provided in the offshore plant for supplying and discharging seawater as a heating heat source; And

And a mixing line connecting the seawater cooling line and the seawater heating line,

There is provided a seawater discharge system capable of mixing the high temperature seawater supplied after being supplied to the cooling heat source with the low temperature seawater discharged after being supplied to the heating heat source and discharging it to the outside of the offshore plant.

Preferably, the apparatus may further include a first three-way valve provided at a point where the mixing line and the sea water cooling line meet, and a second three-way valve provided at a point where the mixing line and the sea water heating line meet.

Preferably, the first buffer tank is provided downstream of the seawater cooling line to mix the high-temperature seawater and the low-temperature seawater, and a second buffer tank provided downstream of the seawater heating line and in which the high-temperature seawater and the low- And selectively discharge seawater from the first and second buffer tanks to the outside of the hull in accordance with the direction of the tidal current.

Preferably, the first buffer tank is provided with a first seawater discharge port for discharging seawater to the outside of the hull, a first seawater discharge valve provided at a front end of the first buffer tank of the seawater cooling line, And a second seawater discharge valve provided at a front end of the second buffer tank of the seawater heating line.

Preferably, a first seawater storage tank provided upstream of the seawater cooling line for storing seawater taken from the outside of the hull, a first strainer for receiving and filtering seawater from the first seawater storage tank, The apparatus may further include a heat exchanger for receiving the filtered seawater and cooling the heat generator of the offshore plant and for exchanging heat with the discharged cooling water.

Preferably, a second seawater storage tank provided upstream of the seawater heating line for storing seawater taken from the outside of the hull, a second strainer for receiving and filtering seawater from the second seawater storage tank, And a vaporizer for receiving the filtered seawater and vaporizing the liquefied natural gas with the seawater as a heat source.

Preferably, the mixing line may be provided to connect the downstream of the heat exchanger of the seawater cooling line to the downstream of the vaporizer of the seawater heating line.

Preferably, a first seawater supply pump provided between the first filter and the heat exchanger for pumping seawater, a first check valve provided between the heat exchanger and the first three-way valve, and a second check valve provided between the second filter and the vaporizer A second seawater supply pump provided between the second evaporator and the second three-way valve for pumping seawater, and a second check valve provided between the evaporator and the second three-way valve.

Preferably, the offshore plant may be a floating storage power plant (FSPP) that stores liquefied natural gas and generates the liquefied natural gas.

According to another aspect of the present invention, there is provided a method of discharging seawater from an offshore plant,

Wherein the high temperature seawater supplied to and discharged from the offshore plant as a cooling heat source and the low temperature seawater supplied to and discharged from the offshore plant as a heat source are discharged to the outside of the offshore plant.

Preferably, a plurality of buffer tanks in which the high-temperature seawater and the low-temperature seawater are mixed are provided apart from each other, and seawater can be selectively discharged from the plurality of buffer tanks according to the tidal direction.

The seawater discharge system of the present invention is provided with a mixing line for connecting the sea water cooling line and the sea water heating line, and the high temperature seawater discharged after being supplied to the cooling heat source is mixed with the low temperature seawater discharged after being supplied to the heating heat source, So that it can be discharged to the outside. By doing so, it is possible to prevent environmental pollution and destruction of the surrounding ecosystem by reducing the temperature difference between the discharged seawater and the surrounding sea.

In addition, a plurality of spaced buffer tanks may be provided to selectively discharge the seawater from each of the buffer tanks according to the change of the algae, thereby preventing the discharged seawater from being re-introduced.

1 schematically shows a method in which seawater was conventionally discharged from an offshore plant.
2 schematically illustrates a seawater discharge system in accordance with an embodiment of the present invention.
FIG. 3 shows only the A portion in more detail in the seawater discharge system shown in FIG.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

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

FIG. 2 schematically illustrates a seawater discharge system according to an embodiment of the present invention, and only a portion A of FIG. 3 is enlarged and shown in detail.

As shown in FIG. 2, the seawater discharge system of the present embodiment is a seawater discharge system provided in an offshore plant, which is provided in a offshore plant and is provided with a sea water cooling line for supplying and discharging seawater as a cooling heat source, And a mixing line connecting the seawater cooling line and the seawater heating line to each other.

By providing the mixing line, the present embodiment allows the high temperature seawater supplied after being supplied to the cooling heat source and the low temperature seawater supplied after being supplied to the heating heat source to be mixed and discharged to the outside of the offshore plant.

A first three-way valve is provided at the point where the mixing line and the sea water cooling line meet, and a second three-way valve is provided at the point where the mixing line and the sea water heating line meet. The hot water from the seawater cooling line can be supplied to the low temperature seawater of the seawater heating line via the mixing line or the low temperature seawater of the seawater heating line can be supplied to the seawater cooling line To the high-temperature seawater in FIG.

A first buffer tank is provided downstream of the seawater cooling line so that the high-temperature seawater and the low-temperature seawater can be mixed evenly. A second buffer tank is provided downstream of the seawater heating line to mix the high-temperature seawater and the low-temperature seawater.

The first and second buffer tanks are spaced apart from the hull so that the first and second tertiary valves are adjusted according to the tidal direction to selectively discharge seawater from the first and second buffer tanks to the outside of the hull It is possible to prevent the discharged seawater from being sucked in again.

The first and second three-way valves allow the direction of the seawater flow in the mixing line to be adjusted, and can be provided with an automatic regulating valve or a manual regulating valve.

Meanwhile, the first buffer tank is provided with a first seawater discharge port for discharging seawater to the outside of the hull, and a first seawater discharge valve is provided at the front end of the first buffer tank of the seawater cooling line.

The second buffer tank is provided with a second seawater discharge port for discharging seawater to the outside of the hull, and a second seawater discharge valve is provided at the front end of the second buffer tank of the seawater heating line.

The first and second seawater discharge openings are provided with openings for discharging seawater, through which a grid may be provided to prevent suspended matters in the seawater from entering the buffer tank.

FIG. 3 is an enlarged view of portion A of FIG. 2 corresponding to the buffer tank and the seawater outlet portion.

A first seawater storage tank for storing seawater taken from the outside of the ship and a first strainer for receiving seawater from the first seawater storage tank are provided upstream of the seawater cooling line. It is installed in the sea water cooling line which exchanges heat with cooling water discharged from the main engine or auxiliary engine of the offshore plant.

A second seawater storage tank for storing seawater taken from the outside of the hull and a second filter for receiving seawater from the second seawater storage tank for filtering the seawater are provided upstream of the seawater heating line, There is also a vaporizer that vaporizes liquefied natural gas into seawater as a heat source.

The first and second filters are provided to prevent foreign matter contained in the seawater from flowing into the heat exchanger or the vaporizer to cause device abnormality or blocking the line. For example, a strainer of a basket type or an auto-back flushing filter .

The first and second seawater storage tanks are respectively provided with seawater inflow ports for collecting and introducing seawater. The seawater inflow port may be provided with a grid for preventing the inflow of floating matters or marine organisms in the seawater.

In addition, the first and second seawater storage tanks may be provided with a chlorine injection device to prevent seawater contained in seawater from sticking.

A first seawater supply pump for pumping the filtered seawater to the heat exchanger is provided between the first filter and the heat exchanger in the seawater cooling line, and a first check valve for preventing seawater backflow is provided between the heat exchanger and the first three- do.

A second seawater supply pump for pumping the seawater filtered between the second filter and the vaporizer to the vaporizer is provided in the seawater heating line and a second check valve for preventing the reverse flow is provided between the vaporizer and the second three-

The first and second seawater supply pumps should be provided so as to have a sufficient head as a pump for transferring seawater to a heat exchanger or a carburetor and each of the first and second seawater supply pumps may be provided in a machine room integrally with a pump and a motor .

The mixing line is provided to connect the downstream of the heat exchanger of the seawater cooling line to the downstream of the vaporizer of the seawater heating line.

Since the seawater flows into the seawater cooling line or the seawater heating line through the mixing line, the first and second check valves are provided to prevent the seawater discharged from flowing back toward the heat exchanger or the vaporizer.

On the other hand, the offshore plant may be a floating storage power plant (FSPP) that stores liquefied natural gas and generates liquefied natural gas.

The FSPP is equipped with a power plant on a marine platform such as a barge floating on the sea. In this embodiment, the above-described vaporizer is used to generate electricity using natural gas, which is generated by vaporizing seawater as a heat source, .

As described above, in this embodiment, the high-temperature seawater supplied to and discharged from the offshore plant as a cooling heat source and the low-temperature seawater supplied and discharged as a heat source to the offshore plant are discharged to the outside of the offshore plant, It is possible to prevent environmental pollution by reducing the temperature difference between seawater and the surrounding sea.

In addition, a plurality of spaced buffer tanks can selectively discharge the seawater along the direction of the algae, thereby preventing the discharged seawater from being re-introduced.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

CL: Sea water cooling line HL: Sea water heating line
ML: Mixed line
SCa: First seawater storage tank SCb: Second seawater storage tank
BTa: first buffer tank BTb: second buffer tank
100: first three-way valve
110: 1st seawater discharge valve
120: First sea water outlet
130: first filter
140: First seawater supply pump
150: heat exchanger
160: First check valve
200: second three-way valve
210: Second seawater discharge valve
220: Second seawater outlet
230: second filter
240: Second seawater supply pump
250: vaporizer
260: Second check valve

Claims (11)

In a seawater discharge system provided in an offshore plant,
A seawater cooling line provided in the offshore plant for supplying and discharging seawater as a cooling heat source;
A seawater heating line provided in the offshore plant for supplying and discharging seawater as a heating heat source; And
And a mixing line connecting the seawater cooling line and the seawater heating line,
Wherein the high temperature seawater supplied after being supplied to the cooling heat source and the low temperature seawater discharged after being supplied to the heating heat source are mixed and discharged to the outside of the offshore plant. The method according to claim 1,
A first three-way valve provided at a point where the mixing line and the seawater cooling line meet; And
Further comprising a second three-way valve provided at a point where the mixing line and the seawater heating line meet. 3. The method of claim 2,
A first buffer tank provided downstream of the seawater cooling line to mix the high temperature seawater and the low temperature seawater;
And a second buffer tank provided downstream of the seawater heating line to mix the high temperature seawater and the low temperature seawater,
And the seawater can be selectively discharged from the first and second buffer tanks to the outside of the hull in accordance with the tidal direction. The method of claim 3,
A first seawater outlet provided in the first buffer tank for discharging seawater to the outside of the ship;
A first seawater discharge valve provided at a front end of the first buffer tank of the seawater cooling line;
A second seawater outlet provided in the second buffer tank for discharging seawater to the outside of the ship; And
And a second seawater discharge valve provided at a front end of the second buffer tank of the seawater heating line. 3. The method of claim 2,
A first seawater storage tank provided upstream of the seawater cooling line for storing seawater taken from outside the hull;
A first filter for receiving and filtering seawater from the first seawater storage tank; And
Further comprising a heat exchanger for receiving the filtered seawater from the first filter and for cooling the exothermic equipment of the offshore plant and for exchanging heat with the discharged cooling water. 6. The method of claim 5,
A second seawater storage tank provided upstream of the seawater heating line for storing seawater taken from outside the hull;
A second filter for receiving and filtering seawater from the second seawater storage tank; And
And a vaporizer for receiving the filtered seawater from the second filter and vaporizing the liquefied natural gas into the seawater as a heat source. The method according to claim 6,
Wherein the mixing line is provided to connect the downstream of the heat exchanger of the seawater cooling line to the downstream of the vaporizer of the seawater heating line. The method according to claim 6,
A first seawater supply pump provided between the first filter and the heat exchanger for pumping seawater;
A first check valve provided between the heat exchanger and the first three-way valve;
A second seawater supply pump provided between the second filter and the vaporizer for pumping seawater; And
Further comprising a second check valve provided between the carburetor and the second three-way valve. 9. The method according to any one of claims 1 to 8,
Wherein the offshore plant is a floating storage power plant (FSPP) that stores liquefied natural gas and generates the liquefied natural gas. In a seawater discharge method of an offshore plant,
Wherein the high temperature seawater supplied to and discharged from the offshore plant as a cooling heat source and the low temperature seawater supplied to and discharged from the offshore plant as a heat source are discharged to the outside of the offshore plant. 11. The method of claim 10,
A plurality of buffer tanks in which high temperature seawater and low temperature seawater are mixed are provided apart from each other,
And the seawater can be selectively discharged from the plurality of buffer tanks according to the direction of the tidal current.

Images