KR101772910B1 - Floating Power Plant - Google Patents

Abstract

A gas turbine that burns gas to produce electricity; A steam generator for generating steam by using waste heat of the exhaust gas discharged from the gas turbine; A steam turbine for generating electricity using steam generated by the steam generator; And a drain device for discharging the seawater used for cooling the steam used in the steam turbine to the outside, wherein the drain device includes a drain pipe for discharging seawater from the steam turbine; And a water supply pipe for receiving seawater from the water discharge pipe and transferring and discharging seawater to a sea area separated from the floating power generation facility by a predetermined distance, wherein the water supply pipe is separated from the floating water generation facility and the movement of the water discharge pipe, A floating power generation facility is started.
According to the floating power generation facility of the present invention, since the water pipe moves separately from the floating power generation facility and the movement of the water pipe, the connection portion of the water pipe can be prevented from being damaged by the movement of the floating power generation facility.

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 drainage device for discharging seawater used for cooling steam to 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). The gas turbine combined cycle can use steam generated by the waste heat generated from the gas turbine 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.

When the cooling water used to cool the steam is discharged to the surroundings, the temperature of the inhaled seawater is increased to be used as the cooling water for cooling the steam, so that the cooling The efficiency can be lowered.

In the case of a floating power generation facility having a small power generation capacity, even if the amount of cooling water used for cooling the steam is small and the cooling water used for cooling the steam is discharged to the vicinity of the floating power generation facility, Is not significant.

Even in the case of a floating power generation facility installed on a flowing river, even if the cooling water used for cooling the steam is discharged to the vicinity of the floating power generation facility, the discharged cooling water flows to the downstream.

However, when floating power generation facilities that generate large scale power are installed on the sea, it is necessary to discharge the cooling water used for cooling the steam to the distant sea.

In the case of on-land power generation facilities, there is no great problem in connecting the piping for discharging the cooling water used for cooling the steam to the distant sea. In the case of floating power generation facilities, however, Since the equipment moves up and down and left and right, the connecting part of the pipe can be continuously applied with force, and the pipe can be easily broken.

The present invention seeks to provide a floating power generation facility including a cooling water drainage 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 gas turbine for generating electric power by burning a gas; A steam generator for generating steam by using waste heat of the exhaust gas discharged from the gas turbine; A steam turbine for generating electricity using steam generated by the steam generator; And a drain device for discharging the seawater used for cooling the steam used in the steam turbine to the outside, wherein the drain device includes a drain pipe for discharging seawater from the steam turbine; And a water pipe for receiving seawater from the water pipe and transferring and discharging the seawater to a sea area separated by a certain distance from the floating power generation facility, wherein the water pipe is separated from the floating water generation facility and the movement of the water pipe, Floating generation facilities are provided.

The drain pipe and the water pipe may not be connected to each other, and the diameter of the water pipe side end of the water pipe may be equal to or larger than the diameter of the water pipe.

The drain pipe may include a stretchable material at the water pipe side end portion, and the water pipe may include a stretchable material at the drain pipe side end portion, and the water pipe and the water pipe may be connected to each other.

The water pipe side end of the water pipe may be located inside the water pipe.

The diameter of the part of the water pipe that transfers the seawater to the sea area located a certain distance from the floating power generation facility may be equal to or larger than the diameter of the water pipe.

According to another aspect of the present invention, there is provided a steam generator for a steam generator, comprising: a steam generator for generating steam; And the drainage pipe and the water pipe are not connected to each other. The water drainage method according to claim 1, wherein the drainage pipe and the water pipe are connected to each other, do.

One embodiment of the floating power generation facility of the present invention includes a drainage device in which a drainage pipe and a water pipe are separated from each other. In another embodiment of the floating power generation facility of the present invention, a drainage pipe It is possible to prevent the connecting portion of the drainage device from being damaged by the movement of the floating power generation facility.

1 is a schematic view of a floating power generation facility according to a first preferred embodiment of the present invention.
2 is a schematic view illustrating a floating power generation facility according to a second preferred embodiment of the present invention.

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.

1 is a schematic view of a floating power generation facility according to a first preferred embodiment of the present invention.

Referring to FIG. 1, a floating power generation facility 10 of the present embodiment includes a gas turbine 100, a steam generator 200, a steam turbine 300, and a drainage device 600.

The gas turbine 100 of the present embodiment is installed in the gas turbine room 11 and generates electric power by burning fuel mixed with air. 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 electricity in the steam turbine 300 is heat-exchanged with the sea water, cooled, and then sent to the fresh water tank 400. The seawater used to cool the steam is discharged to the outside by the drainage device 600 at a high temperature.

The drainage device 600 of the present embodiment includes a drain pipe 610 and a water pipe 620.

The drain pipe 610 of this embodiment has one end connected to the steam turbine 300 to discharge the seawater used to lower the temperature of the steam from the steam turbine 300. The drain pipe 610 may extend from the steam turbine 300 in the sea surface direction and the drain pipe 610 extending in the sea water surface direction may be bent in the gravity direction above the water pipe 620. The drain pipe 610 bent in the gravity direction above the water pipe 620 may be further extended in the gravity direction by a predetermined length and the seawater whose temperature discharged from the steam turbine 300 is increased may be extended in the gravity direction of the drain pipe 610 The water can be discharged downward from the end portion and supplied to the water pipe 620.

The water pipe 620 of this embodiment receives seawater from a drain pipe 610 and discharges the seawater to a sea area separated from the floating power generation facility 10 by a certain distance. The water pipe 620 is not connected to the water pipe 610 so that the water pipe 620 is connected to the floating power generation facility 10 and the water pipe 610 even when the floating power generation facility 10 moves up and down, Can be moved separately from the movement of the drain pipe (610).

The water pipe 620 of this embodiment is located at the lower part of the end of the water pipe 610 through which the sea water is discharged so as to receive seawater discharged from the water pipe 610. The water pipe 620 may extend from the lower part of the end of the water pipe 610 by a predetermined length in the gravity direction and the water pipe 620 extending in the gravity direction may be bent in a direction opposite to the floating power generation equipment 10, It extends to the sea area where seawater is discharged. The seawater whose temperature is increased from the water discharge pipe 610 is conveyed along the water pipe 620 to the sea area separated from the floating power generation facility 10 by a certain distance and discharged.

The diameter of the end of the water pipe 620 on the side of the water pipe 610 is preferably larger than the diameter of the water pipe 610 so that the sea water can be stably supplied from the water pipe 610. The diameter of the portion of the water pipe 620 extending along the bottom surface of the water pipe 620 for transferring the sea water supplied from the water pipe 610 to the far sea area is equal to or larger than the diameter of the water pipe 610 Can be largely formed.

The end of the water pipe 610 on the side of the water pipe 620 may be positioned inside the water pipe 620 so that the sea water discharged from the water pipe 610 can be efficiently supplied to the water pipe 620.

2 is a schematic view illustrating a floating power generation facility according to a second preferred embodiment of the present invention.

The floating power generation facility of the second embodiment shown in FIG. 2 is different from the floating power generation facility of the first embodiment shown in FIG. 1 in that the drainage pipe 610 and the water supply pipe 620 of the drainage device 600 can be expanded There are differences in that they are connected, and the differences are mainly described below. A detailed description of the same components as those of the vaporizing-gas re-liquefaction apparatus for a ship of the first embodiment will be omitted.

Referring to Fig. 2, the drainage device 600 of the present embodiment includes a drain pipe 610 and a water pipe 620 similarly to the first embodiment.

The drain pipe 610 of this embodiment is connected to the steam turbine 300 at one end thereof to discharge seawater used to lower the temperature of the steam from the steam turbine 300, as in the first embodiment. The drain pipe 610 can extend in the sea water surface direction from the steam turbine 300 and the drain pipe 610 extending in the sea water surface direction can be bent in the gravity direction above the water pipe 620 have. The drain pipe 610 curved in the gravity direction above the water pipe 620 can be further extended in the gravity direction by a predetermined length as in the first embodiment and the seawater having a raised temperature from the steam turbine 300 is discharged to the drain pipe 610 in the downward direction and may be supplied to the water pipe 620.

However, unlike the first embodiment, the drain pipe 610 of the present embodiment may include a flexible material at the end on the water pipe 620 side.

The water pipe 620 of this embodiment receives seawater from the water pipe 610 and discharges the seawater to a sea area a certain distance from the floating power generation facility 10, as in the first embodiment. The water pipe 620 is located below the end of the drain pipe 610 through which the seawater is discharged so as to receive seawater discharged from the drain pipe 610 as in the first embodiment, And the water pipe 620 extending in the gravity direction is bent in a direction opposite to the floating power generation facility 10 and extends to a sea area where seawater is discharged along the seabed surface. The seawater whose temperature is increased from the water discharge pipe 610 is conveyed along the water pipe 620 to the sea area separated from the floating power generation facility 10 by a certain distance and discharged.

However, unlike the first embodiment, the water pipe 620 of this embodiment may include an elastic material at an end portion of the water pipe 610 side.

The drainage device 600 of the present embodiment differs from the first embodiment in that the drainage pipe 610 and the water pipe 620 are connected to each other and the drain pipe 610 and the water pipe 620 are formed of separate members But it can be done in one.

Since the drainage device 600 of the present embodiment includes a stretchable material at the connection site, even if the floating power generation facility 10 moves up and down and left and right by an external force such as waves or algae as in the first embodiment, Can be moved separately from the movements of the floating power generation facility 10 and the drain pipe 610.

Even when the drain pipe 610 and the water pipe 620 are integrally formed, the upper and lower portions of the floating power generation facility 10 can be moved in different directions about the portion including the expandable and contractible material, So that the connecting portion of the connecting member 600 can be maintained without being easily broken.

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 District 100: Gas Turbine
200: Steam generator 300: Steam turbine
400: Fresh Water Tank 600: Drainage device
610: Water pipe 620: Water pipe

Claims (6)

A gas turbine that burns gas to produce electricity;
A steam generator for generating steam by using waste heat of the exhaust gas discharged from the gas turbine;
A steam turbine for generating electricity using steam generated by the steam generator; And
And a drain device used to cool the steam used in the steam turbine to discharge the 'seawater having a high temperature' to the outside,
Wherein the drainage device comprises:
A drain pipe for discharging the 'high temperature seawater' from the steam turbine; And
And a water pipe for receiving the sea water having a higher temperature from the water pipe and transferring the sea water having a temperature higher than a predetermined distance to the sea water,
Wherein the water pipe moves separately from the floating power generation facility and the movement of the water pipe so that the connection portion between the water pipe and the water pipe is not damaged by the movement of the floating power generation facility,
Wherein the temperature of the seawater transferred and discharged by the water pipe does not affect the temperature of seawater supplied from the outside of the floating power generation facility to cool the steam turbine. . The method according to claim 1,
The water pipe and the water pipe are not connected to each other,
Wherein a diameter of the water pipe side end portion of the water pipe is formed to be equal to or larger than a diameter of the water pipe. The method according to claim 1,
Wherein the drain pipe includes a stretchable material at the water pipe side end,
Wherein the water pipe includes a stretchable material at the drain pipe side end,
Wherein the water pipe and the water pipe are connected to each other. The method of claim 2,
And the water pipe side end of the water pipe is located inside the water pipe. The method of claim 2,
Wherein a diameter of a portion of the water pipe for transferring the seawater to a sea area separated from the floating power generation facility by a distance is equal to or larger than a diameter of the water pipe. The 'warmer seawater' used to cool the steam is discharged through the drain pipe to the outside of the floating power generation facility,
The water pipe having the 'raised temperature', which is discharged to the outside of the floating power generation facility through the water pipe,
The 'high temperature sea water' supplied by the water pipe is transferred to a sea area separated from the floating power generation facility by a predetermined distance,
The water pipe and the water pipe are not connected to each other, so that the connecting portion between the water pipe and the water pipe is not damaged by the movement of the floating power generation facility,
Wherein the 'high temperature sea water' conveyed and discharged by the water pipe does not affect the temperature of seawater supplied from the outside of the floating power generation facility to cool the steam.

Images