KR101772912B1 - Floating Power Plant - Google Patents

Abstract

A floating power generation facility installed in the sea to produce electric power, comprising: a gas turbine for generating electric power by burning gas; A seawater supply device for supplying seawater to the floating power generation facility; And a seawater storage unit installed in the floating power generation facility for temporarily storing the seawater supplied from the seawater supply device, wherein the seawater supply device includes: Conveying piping for conveying; A vertical pipe through which the sea water transferred by the transfer pipe is filled; And a supply pipe for supplying seawater filled in the vertical pipe to the seawater receiving portion, wherein the vertical pipe and the supply pipe are not connected to each other.
According to the floating power generation facility of the present invention, since the seawater supply device configured in a state in which the supply pipe and the vertical pipe are not connected to each other is included, the connection portion of the seawater supply device can be prevented from being damaged by the movement of the floating power generation equipment have.

Description

{Floating Power Plant}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floating power generation facility, and more particularly, to a floating power generation facility including a cooling water supply device for drawing seawater used for cooling steam from a distant sea.

Gas Turbine is composed of a compressor, a combustion chamber, and a turbine. It compresses fuel such as gas with a compressor, sends the compressed fuel to the combustion chamber, burns the fuel in the combustion chamber, High pressure gas is expelled into the turbine while expanding to rotate the turbine.

Power generation using only a gas turbine can produce an output of about 25 MW to 500 MW, which is simpler in construction than steam turbine power generation, has a lower construction cost, and has a short start-up time.

In recent years, float-type power generation facilities using gas turbines have been built not only on land but also on offshore water, and floating power generation facilities are not required to secure land, unlike land, have.

A steam turbine, also referred to as a steam turbine, includes a nozzle for converting thermal energy of steam into kinetic energy, and a turbine blade for converting kinetic energy into mechanical energy. In the steam turbine, high-temperature and high-pressure steam is ejected from a nozzle or a fixed blade and inflated, and the generated high-speed steam flow hits a rotating turbine blade to rotate the shaft by its recoil action. The steam used in the steam turbine is cooled and watered, then heated again and supplied to the steam turbine, and this process is repeated and circulated.

Steam turbine power generation and gas turbine power generation are less efficient than power generation using a four-stroke engine or a two-stroke engine. To improve the low efficiency of the steam turbine and the gas turbine, a gas turbine combined cycle Gas Turbine Combined Cycle). In the gas turbine combined cycle, the steam generated by the waste heat generated in the gas turbine can be used to drive the steam turbine, thereby increasing the efficiency by approximately 35% to 50%. Recently, many power plants using gas turbine combined cycle are being built.

In order to cool the steam used in the steam turbine, heat can be exchanged between the steam and the cooling water, and seawater can be used as cooling water for cooling the steam.

Although sea water for cooling steam can be used near the floating power generation facility, if the sea water is supplied from the distant sea, the cooling efficiency can be increased because the lower temperature sea water can be used as the cooling water. In addition, when sea water is supplied from a distant sea, the seawater in the deep sea is relatively less floatable, which has the advantage of simplifying or eliminating the filtration device.

On the other hand, in the case of on-land power generation facilities, there is no great problem in installing piping for drawing seawater from distant sea. However, in case of floating power generation facilities, floating power generation facilities The force can be continuously applied to the connection portion of the pipe, and the pipe can be easily broken.

The present invention seeks to provide a floating power generation facility including a seawater supply device capable of withstanding the motion of floating power generation facilities installed on the sea.

According to an aspect of the present invention, there is provided a floating power generation facility installed in a sea and generating electric power, comprising: a gas turbine for generating electric power by burning gas; A seawater supply device for supplying seawater to the floating power generation facility; And a seawater storage unit installed in the floating power generation facility for temporarily storing the seawater supplied from the seawater supply device, wherein the seawater supply device includes: Conveying piping for conveying; A vertical pipe through which the sea water transferred by the transfer pipe is filled; And a supply pipe for supplying seawater filled in the vertical pipe to the seawater receiving portion, wherein the vertical pipe and the supply pipe are not connected.

The floating generator includes a steam generator for generating steam using waste heat of the exhaust gas discharged from the gas turbine; And a steam turbine for generating electric power using steam generated by the steam generator, wherein the seawater stored in the seawater receiving portion is supplied to the steam turbine, and the steam used in the steam turbine is cooled As the cooling water.

The lower portion of the vertical pipe may be installed on the bottom of the seabed.

The floating power generation equipment may further include a pump installed in the supply pipe.

The floating power generation facility includes an air discharge unit for discharging the air inside the seawater storage unit to the outside; And an air hole formed to pass through the side wall of the floating power generation facility from the seawater receiving portion; ≪ / RTI >

The seawater supply device may further include a sediment receiving unit formed below the vertical piping to provide a space in which the sediment from the vertical piping can be accumulated.

According to another aspect of the present invention, there is provided a method for supplying seawater to a floating power generation facility installed in a sea and generating electricity, the method comprising: 1) 2) filling the vertical pipe with the seawater transferred in the step 1), 3) supplying the seawater filled in the vertical pipe in the step 2) to the floating power generation facility by the supply pipe, Wherein the supply pipe is not connected to the supply pipe.

According to the floating power generation facility of the present invention, since the seawater supply device configured in a state in which the supply pipe and the vertical pipe are not connected to each other is included, the connection portion of the seawater supply device can be prevented from being damaged by the movement of the floating power generation equipment have.

1 is a schematic view illustrating a floating power generation facility according to a preferred embodiment of the present invention.
FIG. 2 is a schematic view showing the state of FIG. 1 viewed from direction A. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following examples are intended to illustrate the present invention and should not be construed as limiting the scope of the present invention.

FIG. 1 is a schematic view of a floating power generation facility according to a preferred embodiment of the present invention, and FIG. 2 is a schematic view illustrating a view of FIG. 1 viewed from direction A. In FIG. 2, the transmission tower 20 is omitted.

1, the floating power generation facility 10 of the present embodiment includes a gas turbine 100, a steam generator 200, a steam turbine 300, a seawater supply device 640, and a seawater receiving portion 610, .

The gas turbine 100 of the present embodiment is installed in the gas turbine chamber 11 and generates electric power by burning fuel such as gas. The gas turbine 100 operates and the generated exhaust gas is sent to the steam generator 200 to heat the fresh water supplied from the fresh water tank 400. The exhaust gas, which has supplied energy to heat the fresh water in the steam generator 200, is discharged to the outside through the upper portion of the steam generator 200 in a low temperature state.

The gas turbine 100 of the present embodiment can be installed on the forward side of the gas turbine room 11. The floating power generation facility 10 of the present embodiment includes a transmission tower 20 installed on one deck and a transmission tower 20 The gas turbine 100 may be installed on the side of the residence 30 of the gas turbine room 11. [

In the steam generator 200 of this embodiment, one end is connected to the gas turbine 100 and the other end is connected to the outside. In addition, a pipe 250 for supplying steam to the steam turbine 300 is connected to the side surface. The steam generator 200 generates steam by heating fresh water supplied from the fresh water tank 400 by the waste heat of the exhaust gas supplied from the gas turbine 100. The steam generated in the steam generator 200 is sent to the steam turbine 300 through the pipe 250, and the exhaust gas used to generate steam is discharged to the outside in a state where the temperature is lowered.

The steam generator 200 of the present embodiment can be installed in the gas turbine chamber 11 together with the gas turbine 100. When the gas turbine 100 is installed on the forward side of the gas turbine chamber 11, The generator 200 is installed on the stern side of the gas turbine chamber 11 and when the gas turbine 100 is installed on the side of the housing 30 of the gas turbine chamber 11, And can be installed on the transmission tower 20 side of the chamber 11. It is possible to prevent the exhaust gas discharged from the steam generator 200 from flowing into the housing 30 as much as possible by installing the steam generator 200 on the transmission tower 20 side opposite to the housing 30. [

The steam turbine 300 of the present embodiment is installed in the steam turbine chamber 12 and a pipe 250 for supplying steam from the steam generator 200 is connected to the side surface. The steam turbine 300 supplies steam generated in the steam generator 200 through the pipe 250 to produce electric power. The steam used to produce electric power in the steam turbine 300 is heat-exchanged with the cooling water, cooled, and then sent to the fresh water tank 400. The cooling water used to cool the steam is discharged to the outside at a high temperature.

The seawater supply device 640 of the present embodiment transfers the seawater from the sea area a certain distance away from the floating power generation facility 10 and then supplies the transferred seawater to the seawater receiving part 610. The seawater supply device 640 preferably includes a transfer piping 642, a vertical piping 641 and a supply piping 630 and is disposed on the opposite side of the seam 40 from the floating power generation facility 10 Do.

The transfer piping 642 of this embodiment transfers seawater from the sea area a certain distance from the floating power generation facility 10 to the vertical piping 641 and extends along the sea floor.

The floating power generation facility (10) is usually installed in the offshore. If the sea water to be used as the cooling water is drawn from the sea floor of the distant sea, the lower temperature seawater can be used as the cooling water to improve the cooling efficiency. And the amount of floating matters is reduced.

The vertical pipe 641 of this embodiment extends vertically from the upper surface of the sea surface to the bottom of the sea floor, and its side is connected to one end of the transfer pipe 642. Since the vertical pipe 641 of this embodiment is installed on the bottom surface of the sea bottom, it can be firmly installed so as not to be shaken by an external force such as the flow of seawater. The vertical pipeline 641 is filled with the sea water conveyed through the transfer pipe 642 to the same level as the sea level.

The supply pipe 630 of the present embodiment has one end located inside the vertical pipe 641 and the other end located inside the seawater receiving portion 610 and the seawater contained in the vertical pipe 641 is received by the seawater receiving portion 610, . The supply pipe 630 extends upward from the end of the vertical pipe 641 in parallel with the vertical pipe 641 and extends in the direction of the sea surface after being bent over the vertical pipe 641 toward the floating power generation equipment 10 . The supply pipe 630 extending in the direction of the sea surface extends through the side wall of the floating power generation facility 10 and then extends to the inside of the seawater receiving portion 610 and is connected to the end portion of the supply pipe 630 on the sea water receiving portion 610 side May be formed to face downward.

According to the floating power generation facility 10 of the present embodiment, since the supply piping 630 connected to the floating power generation facility 10 and the vertical piping 641 are separated from each other, It is possible to prevent the connection portion of the pipe from being damaged.

A pump can be installed in the supply pipe 630 of the present embodiment so that seawater in the vertical pipe 641 can be supplied to the seawater receiving portion 610 along the supply pipe 630. [

The seawater supply device 640 of the present embodiment may further include a sediment receiving portion 690 formed below the vertical pipe 641. The seawater transferred through the transfer piping 642 is supplied to the vertical piping 641 and can be rapidly lowered in flow rate and materials having a larger specific gravity than the seawater in the vertical piping 641 can sink. The portion 690 provides a space in which the settled materials in the vertical pipe 641 can accumulate.

The seawater storage unit 610 of the present embodiment is formed inside the floating power generation facility 10 and temporarily stores seawater supplied through the supply pipeline 630. The seawater storage unit 610 may be installed in the steam turbine chamber 12 and the seawater stored in the seawater storage unit 610 may be supplied to the steam turbine 300 through the cooling water supply pipe 650, ) Is used as cooling water to cool the steam used.

The floating power generation facility 10 of the present embodiment includes an air discharge unit 620 for discharging the air inside the seawater storage unit 610 to the outside; And an air hole (670) formed through the side wall of the floating power generation facility (10) from the seawater receiving portion (610). ≪ / RTI > The air discharge unit 620 and the air hole 670 of the present embodiment discharge the air inside the seawater receiving unit 610 to the outside so that seawater can flow smoothly into the seawater receiving unit 610.

The floating power generation facility 10 of the present embodiment includes a seawater supply unit 680 installed on a sidewall of the floating power generation facility 10 under the seawater receiving unit 610 to receive seawater into the seawater receiving unit 610, As shown in FIG. The seawater supply unit 680 is designed to be openable and closable, and if necessary, the seawater around the floating power generation facility 10 can be introduced into the seawater storage unit 610.

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. It is.

10: Floating power generation facility 11: Gas turbine room
12: Steam turbine chamber 20: Transmission tower
30: Residential area 40: Seagrass
100: Gas Turbine 200: Steam generator
300: Steam Turbine 400: Fresh Water Tank
610: Seawater storage section 620: Air discharge section
630: Supply piping 640: Seawater supply device
641: Vertical piping 642: Transfer piping
650: Cooling water supply pipe 670: Air hole
680: Seawater supply part 690: Sediment receiving part

Claims (8)

In a floating power generation facility installed in the sea to produce electric power,
A gas turbine that burns gas to produce electricity;
A seawater supply device for supplying seawater to the floating power generation facility;
A seawater storage unit installed in the floating power generation facility for temporarily storing seawater supplied from the seawater supply unit; And
And a seawater supply unit installed on a sidewall below the seawater receiving unit of the floating power generation facility for introducing seawater into the seawater receiving unit,
An air discharge unit for discharging the air inside the seawater storage unit to the outside; And an air hole formed to pass through the side wall of the floating power generation facility from the seawater receiving portion; ≪ / RTI >
The seawater supply device includes:
A transfer pipe for transferring the seawater from a sea area distant from the floating power generation facility;
A vertical pipe through which the sea water transferred by the transfer pipe is filled;
A supply pipe for supplying seawater filled in the vertical pipe to the seawater storage unit; And
And a sediment receiving part formed at the lower part of the vertical piping to provide a space in which the materials sinking in the vertical piping can be accumulated,
Wherein the vertical piping extends vertically from the transfer piping so that the sea water transferred through the transfer piping is supplied to the vertical piping and the flow rate is slowed so that the seawater is supplied to the sediment receiving portion, Substances are submerged,
And the vertical pipe and the supply pipe are not connected to each other. The method according to claim 1,
A steam generator for generating steam by using waste heat of the exhaust gas discharged from the gas turbine; And
And a steam turbine for generating electricity using steam generated by the steam generator,
Wherein the seawater stored in the seawater receiving portion is supplied to the steam turbine and used as cooling water for cooling the steam used in the steam turbine. The method according to claim 1 or 2,
And the lower portion of the vertical pipe is installed on the bottom of the sea floor. The method according to claim 1 or 2,
Further comprising a pump installed in the supply pipe. delete delete delete delete

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