KR102380316B1 - Fuel gas cooling systems and gas turbine plants - Google Patents

Abstract

A fuel gas cooling system and gas turbine plant WHEREIN: The gas cooler 39 which makes cooling water (CW) contact with compressed fuel gas (FC) as fuel gas to cool, and the cooling water (CW) stored in the gas cooler 39. a cooling water discharge line L14 for discharging, a siphon unit 81 provided in the cooling water discharge line L14, and a gaseous phase portion 72 of the cooling water pit 40 as an inert gas storage unit for storing inert gas; A gas line L24 having one end communicating with the siphon unit 81 and the other end communicating with the gas phase unit 72 is provided.

Description

Fuel gas cooling systems and gas turbine plants

This invention relates to the cooling system of the fuel gas which cools the fuel gas supplied to a gas turbine, for example, and the gas turbine plant provided with the cooling system of this fuel gas.

A combined cycle plant first generates electricity by driving a gas turbine using natural gas or the like as a fuel, and then a heat recovery boiler recovers heat from the exhaust gas of the gas turbine to generate steam, The steam turbine drives the steam turbine to generate the second power generation. And the steam after use which drove a steam turbine is cooled by a condenser, it becomes condensate, and is returned to a waste heat recovery boiler.

In this combined cycle plant, as a fuel supplied to a gas turbine, blast furnace gas (BFG, Blast Furnace Gas) may be used. Blast furnace gas is generated when iron ore is reduced in a blast furnace to produce pig iron, and is high in temperature. And this blast furnace gas turns into high-temperature, high-pressure fuel gas by a gas compressor, and is supplied to the combustor of a gas turbine. Therefore, the gas cooler which cools the blast furnace gas is provided in the fuel gas supply line.

As a power plant provided with a gas cooler, there exists a thing described in the following patent document 1, for example. The power plant described in Patent Document 1 supplies a part of blast furnace gas to a gas cooler, cools it by contacting cooling water with the blast furnace gas, mixes a fuel gas with a lowered temperature with high-temperature blast furnace gas, and then supplies it to a gas turbine. will be.

International Publication No. 2012-099046

In the power plant described in Patent Document 1, the gas cooler is provided with a hopper for storing cooling water at the bottom, and a cooling water return pipe for returning the cooling water to the cooling water pit is connected to the hopper, and a siphon brake is provided on the cooling water return pipe there is. This siphon brake part stops discharge|emission of cooling water from the hopper of a gas cooler by air entering inside when supply of cooling water to a gas cooler is stopped, and prevents fuel gas leakage from a gas cooler. However, since the siphon brake part is open to the atmosphere, the air sucked in from the opening part mixes with the cooling water, and oxygen in the air mixes with the fuel gas in the gas cooler. Then, the fuel gas mixed with oxygen is supplied to a gas turbine through an electric dust collector, and there exists a possibility of exerting a bad influence with respect to an electric dust collector or a gas turbine.

This invention solves the subject mentioned above, and an object of this invention is to provide the fuel gas cooling system and gas turbine plant which ensure safety and aim at the improvement of reliability.

The fuel gas cooling system of the present invention for achieving the above object includes a gas cooler cooling the fuel gas by contacting cooling water, a discharge path for discharging the cooling water stored in the gas cooler, and a siphon provided in the discharge path It is characterized in that it comprises a portion, an inert gas storage portion for storing an inert gas, and a communication path in which one end communicates with the siphon portion and the other end communicates with the inert gas storage portion.

Accordingly, the fuel gas is cooled by contact with the coolant by the gas cooler, and the coolant that has cooled the fuel gas is stored in the lower portion of the gas cooler and then discharged to the outside through the discharge path. At this time, even if the supply of cooling water to the gas cooler is stopped, if the amount of cooling water in the lower part of the gas cooler decreases, the inert gas is supplied from the communication path to the siphon part of the discharge path, so that the discharge of the cooling water from the gas cooler is stopped. Thus, a predetermined amount of cooling water is secured in the lower part of the gas cooler. And, since the siphon part communicates with the inert gas storage part through the discharge path, oxygen in the air does not enter the gas cooler and mix with the fuel gas, and safety can be ensured and reliability can be improved.

In the fuel gas cooling system of this invention, the said inert gas storage part is maintained by the static pressure higher than atmospheric|atmosphere, It is characterized by the above-mentioned.

Therefore, since the inert gas storage portion is maintained at a static pressure higher than the atmospheric pressure, when the supply of cooling water to the gas cooler is stopped and the amount of cooling water in the lower portion of the gas cooler is decreased, the inert gas of the inert gas storage portion is communicated through the communication path. It is possible to stop discharging the cooling water from the gas cooler by appropriately supplying it to the siphon unit.

In the fuel gas cooling system of the present invention, a cooling water storage unit for storing cooling water discharged through the discharge path is provided, and the inert gas storage unit is provided in the cooling water storage unit.

Accordingly, since the other end of the communication path, at which one end communicates with the siphon unit, communicates with the inert gas storage unit in the cooling water storage unit, it is not necessary to separately provide the inert gas storage unit, and it is possible to suppress the enlargement of the equipment.

In the fuel gas cooling system of the present invention, a wet electric dust collector for removing foreign substances contained in the fuel gas cooled by the gas cooler is provided, the wet electric dust collector is provided with a washing water reservoir, and the washing water reservoir is provided. It is characterized in that the inert gas storage unit is provided therein.

Accordingly, since the other end of the communication path, at which one end communicates with the siphon unit, communicates with the washing water storage unit of the wet electrostatic precipitator, there is no need to separately provide an inert gas storage unit, and the size of the equipment can be suppressed.

Moreover, the gas turbine plant of this invention is provided with the gas turbine which has a compressor, a combustor, and a turbine, and the said fuel gas cooling system which cools the fuel supplied to the said combustor, It is characterized by the above-mentioned.

Accordingly, the fuel gas is cooled by contact with the cooling water by the gas cooler, and is supplied to the combustor of the gas turbine through the fuel gas supply line to be burned. On the other hand, the cooling water which cooled fuel gas is discharged|emitted to the outside through the discharge path|route after being stored in the lower part of the gas cooler. At this time, since the siphon part communicates with the inert gas storage part through the discharge path, oxygen in the air does not enter the gas cooler and mix with the fuel gas, and even if an electric dust collector is disposed in the fuel gas supply line, the fuel gas does not adversely affect the electrostatic precipitator or combustor, ensuring safety and improving reliability.

ADVANTAGE OF THE INVENTION According to the fuel gas cooling system and gas turbine plant of this invention, safety can be ensured and the improvement of reliability can be aimed at.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram which shows the combined cycle plant to which the cooling system of the fuel gas of this embodiment was applied.
2 : is a schematic block diagram which shows the cooling system of the fuel gas of this embodiment.
3 : is a schematic block diagram which shows the modification of the cooling system of the fuel gas of this embodiment.

EMBODIMENT OF THE INVENTION Hereinafter, based on drawing, preferred embodiment of the fuel gas cooling system which concerns on this invention, and a gas turbine plant is described in detail. In addition, this invention is not limited by this embodiment, Moreover, when there are two or more embodiments, what is comprised combining each embodiment is also included.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram which shows the combined cycle plant to which the cooling system of the fuel gas of this embodiment was applied.

In the present embodiment, as shown in FIG. 1 , the combined cycle plant 10 includes a gas turbine 11 , a heat recovery boiler (HRSG) 12 , a steam turbine 13 , and a generator 14 . ) is provided. The combined cycle plant 10 has a uniaxial type in which the rotation shaft of the gas turbine 11 and the rotation shaft of the steam turbine 13 are arranged in a straight line, and the generator 14 is connected to the rotation shaft. However, the combined cycle plant 10 is not limited to a uniaxial type, The rotation shaft of the gas turbine 11 and the rotation shaft of the steam turbine 13 may be arrange|positioned separately.

The gas turbine 11 has a compressor 21 , a combustor 22 , and a turbine 23 , and the compressor 21 and the turbine 23 can rotate integrally by a rotor (rotation shaft) 24 . are closely connected The compressor 21 compresses the air A sucked from the air intake line L1 through the air intake port, and the filter 25 is provided in the air intake line L1. The combustor 22 includes compressed air AC supplied from the compressor 21 through the compressed air supply line L2 and fuel gas F (compressed fuel gas FC) supplied from the fuel gas supply line L3 . )) is mixed and burned. The turbine 23 is rotationally driven by the combustion gas FG supplied from the combustor 22 through the combustion gas supply line L4.

The exhaust heat recovery boiler 12 generates steam (superheated steam) S by exhaust gas EG discharged from a gas turbine 11 (turbine 23) through an exhaust gas discharge line L5. will make it Although not shown, the waste heat recovery boiler 12 has a superheater, an evaporator, and an economizer as a heat exchanger. The exhaust heat recovery boiler 12 generates steam S by passing the exhaust gas EG from the gas turbine 11 through the inside, thereby recovering heat in the order of a superheater, an evaporator, and an economizer. In addition, the exhaust heat recovery boiler 12 is connected to a chimney 26 through an exhaust gas discharge line L6 for discharging the spent exhaust gas EG that has generated steam S.

The steam turbine 13 is driven by the steam S generated by the heat recovery boiler 12 . The steam turbine 13 has a turbine 27 , and the rotating shaft 28 is connected to the rotor 24 of the gas turbine 11 in a straight line. In addition, a steam supply line L7 for supplying the superheated steam of the superheater of the heat recovery boiler 12 to the turbine 27 is provided, and the spent steam S that drives the turbine 27 is transferred to the heat recovery boiler ( A vapor recovery line L8 returning to the reheater of 12) is provided, and a condenser 29 and a condensate pump 30 are provided in the vapor recovery line L8. The condenser 29 cools the steam S discharged|emitted from the turbine 27 with cooling water (for example, seawater), and sets it as condensate W.

Moreover, the gas turbine 11 compresses the blast furnace gas BFG discharged|emitted from the blast furnace (not shown) as fuel gas F, and then supplies it to the combustor 22. As shown in FIG. The gas compressor 31 which compresses BFG as fuel gas F is an axial compressor, has the turbine 32, and the driven gear 34 is being fixed to the edge part of the rotating shaft 33. As shown in FIG. In the turbine 27 of the steam turbine 13 , a drive gear 35 is fixed to an end of a rotation shaft 28 , and the drive gear 35 meshes with a driven gear 34 . Therefore, when the turbine 27 of the steam turbine 13 drives, the rotational force is transmitted from the rotation shaft 28 to the rotation shaft 33 via the drive gear 35 and the driven gear 34, and the gas compressor 31 ) of the turbine 32 is driven and rotated.

The gas compressor 31 is connected to a fuel gas supply line L11 through which BFG as the fuel gas F is supplied to a gas inlet. The fuel gas supply line L11 is provided with an on/off valve 36 and an electric dust collector (wet or dry) 37, and the electric dust collector 37 collects foreign matter such as dust contained in the fuel gas F. to remove Moreover, as for the fuel gas supply line L3, the fuel gas return line L12 which returns a part of compressed fuel gas FC compressed by the gas compressor 31 to the fuel gas supply line L11 as excess gas is provided. there is. One end of the fuel gas return line L12 is connected to the fuel gas supply line L3 , and the other end is connected between the on-off valve 36 and the electric dust collector 37 in the fuel gas supply line L11 . has been The fuel gas return line L12 is provided with a bypass valve 38 and a gas cooler 39 .

The gas cooler 39 cools a part of compressed fuel gas FC as surplus gas by contacting cooling water. The cooling water pit 40 is disposed below the gas cooler 39 , and a cooling water supply line L13 and a cooling water discharge line L14 are provided between the gas cooler 39 and the cooling water pit 40 . The cooling water supply line L13 is provided with a cooling water supply pump 41 , and by driving the cooling water supply pump 41 , the cooling water of the cooling water pit 40 is supplied from the cooling water supply line L13 to the gas cooler 39 . and cooling water by spraying the compressed fuel gas (FC). The cooling water which has cooled the compressed fuel gas FC is returned to the cooling water pit 40 from the cooling water discharge line L14 by its own weight.

Therefore, when the combined cycle plant 10 is operated, the BFG as the fuel gas F is converted to the electrostatic precipitator 37 by the gas compressor ( 31) to become compressed fuel gas (FC), and is supplied to the combustor 22 . At this time, after a part of compressed fuel gas FC is cooled by the gas cooler 39 as excess gas, it is returned to the fuel gas supply line L11. In the gas turbine 11, the compressor 21 compresses the air A, and the combustor 22 mixes the supplied compressed air AC and the compressed fuel gas FC and burns them. At this time, the gas compressor 31 compresses BFG as fuel gas F, sets it as compressed fuel gas FC, and supplies it to the combustor 22. The turbine 23 is rotationally driven by the combustion gas FG supplied from the combustor 22 . Moreover, the exhaust gas EG discharged|emitted from the gas turbine 11 (turbine 23) is sent to the heat recovery boiler 12, and the heat recovery boiler 12 produces|generates steam (superheated steam) S. And, the steam (S) is sent to the steam turbine (13). The turbine 27 is rotationally driven by this steam S. The generator 14 generates electricity by driving and rotating the rotor 24 and the rotating shaft 28 by the gas turbine 11 and the steam turbine 13 .

2 : is a schematic block diagram which shows the cooling system of the fuel gas of this embodiment.

The fuel gas cooling system of this embodiment cools compressed fuel gas FC supplied to the combustor 22 of the gas turbine 11 as fuel gas. As shown in FIG. 2 , the gas cooler 39 includes a housing 51 , a header 52 , a spray nozzle 53 , and a hopper 54 . The housing 51 has a hollow shape, the gas introduction part 61 is provided at the lower part, and the gas discharge part 62 is provided at the upper part. Moreover, the housing 51 is provided with the 1st guide member 63 continuous to the gas introduction part 61 inside, and opposes the upper direction of the 1st guide member 63, The 2nd guide member 64 is provided. By being provided, the curved passage 65 is provided between the gas introduction part 61 and the gas exhaust part 62 .

The header 52 is disposed above the outside of the housing 51 , and the downstream end of the cooling water supply line L13 is connected thereto. A plurality of spray nozzles 53 are arranged in the bent passage 65 in the housing 51 , and the cooling water line L21 from the header 52 is connected. The hopper 54 is disposed around the gas introduction part 61 under the header 52 , and the cooling water CW sprayed from the plurality of spray nozzles 53 is temporarily stored. The hopper 54 communicates with the upstream end of the cooling water discharge line (discharge path) L14 at the lower part.

The cooling water pit (cooling water storage part) 40 is disposed below the gas cooler 39 , and can store a predetermined amount of cooling water CW. The cooling water pit 40 is composed of a liquid phase portion 71 and a gas phase portion (inert gas storage portion) 72 , the cooling water (CW) is stored in the liquid phase portion 71 , and is inert in the gas phase portion 72 . A gas (eg nitrogen) (N) is charged. In addition, the upstream end of the cooling water supply line L13 communicates with the liquid phase portion 71 , and the downstream end of the cooling water discharge line L14 communicates with the liquid phase portion 71 . The cooling water supply line L13 is provided with a cooling water supply pump 41 . In addition, the cooling water pit 40 is provided with an inert gas supply line L22 for supplying and bubbling the inert gas N to the liquid phase portion 71 . Therefore, in the cooling water pit 40, the gaseous phase part 72 is maintained at a static pressure higher than the atmospheric pressure. In addition, the cooling water pit 40 is provided with a gas discharge line L23 for discharging carbon monoxide (CO) dissolved in the cooling water CW of the liquid phase portion 71 and reaching the gas phase portion 72 .

In the cooling water discharge line L14 , the siphon part 81 is provided in the intermediate part, and the gas line (communication path) L24 communicates with the siphon part 81 . The siphon part 81 and the gas line L24 constitute a siphon break part. This siphon brake unit stops discharging of the cooling water CW from the gas cooler 39 even when the cooling water supply pump 41 is stopped and the supply of the cooling water CW to the gas cooler 39 is stopped. ), by securing a predetermined amount of cooling water CW in the hopper 54 , the temperature increase of the gas cooler 39 by the compressed fuel gas FC is suppressed.

The siphon part 81 has the 1st vertical part 82, the 2nd vertical part 83, and the horizontal part 84 which connects the 1st vertical part 82 and the 2nd vertical part 83. . In addition, the 1st vertical part 82 and the 2nd vertical part 83 may be inclined. And the horizontal part 84 is set so that the position in the vertical direction may become the upper limit level of the cooling water CW stored in the hopper 54 of the gas cooler 39. As shown in FIG. And, as for the siphon part 81, one end of the gas line L24 communicates with the upper part of the horizontal part 84, and the gas line L24 has the other end connected to the gas phase part 72 of the cooling water pit 40. is connected Here, the horizontal part 84 is a pipe constituting a part of the gas line L24, and the gas line L24 is connected to the upper part of the pipe, and the position of the lower part of the pipe is the hopper ( 54) is the upper limit level of the cooling water (CW) stored in the.

In the fuel gas cooling system of this embodiment configured as described above, the compressed fuel gas FC is supplied to the gas cooler 39 via the fuel gas return line L12, while the cooling water CW is supplied with the cooling water. By driving the pump 41 , the cooling water is supplied from the cooling water pit 40 to the gas cooler 39 by the cooling water supply line L13 . In the gas cooler 39 , compressed fuel gas FC flows from the gas inlet 61 through the bent passage 65 to the gas outlet 62 , and the cooling water CW is supplied by the spray nozzle 53 to the bent passage. By being sprayed on 65, compressed fuel gas FC comes into contact with cooling water CW and is cooled. The cooled compressed fuel gas FC flows from the fuel gas return line L12 to the fuel gas supply line L11 , mixes with the fuel gas F, and flows to the electric dust collector 37 . On the other hand, after cooling the compressed fuel gas FC, the cooling water CW is temporarily stored in the hopper 54 and then returned to the cooling water pit 40 by the cooling water discharge line L14 by its own weight.

When the cooling water supply pump 41 is stopped while the gas cooler 39 is operating, the supply of the cooling water CW from the cooling water pit 40 to the gas cooler 39 through the cooling water supply line L13 is stopped. Then, the gas cooler 39 is stored in the hopper 54 at the point that the cooling water CW stored in the hopper 54 is continuously returned to the cooling water pit 40 by the cooling water discharge line L14. The amount of stored cooling water (CW) decreases. Then, when the storage amount of the cooling water CW in the hopper 54 is less than the lower limit level, the inert gas N of the cooling water pit 40 passes through the gas line L24 to the horizontal portion 84 of the siphon unit 81 . At the point supplied to , the discharge of the cooling water CW from the hopper 54 through the cooling water discharge line L14 is stopped due to the siphon break effect, and a predetermined amount of cooling water is supplied to the hopper 54 of the gas cooler 39 . is secured

In addition, at this time, there is a possibility that the inert gas N supplied to the siphon unit 81 may enter the gas cooler 39 through the cooling water discharge line L14 and be mixed into the compressed fuel gas FC. However, since the inert gas N does not contain air, the compressed fuel gas FC containing the inert gas N in the gas cooler 39 passes through the electrostatic precipitator 37 or after that, Even if it is supplied to the combustor 22 of the gas turbine 11, it does not exert a bad influence on the electric dust collector 37 or the combustor 22.

In addition, in the above-described embodiment, the siphon part 81 is provided in the cooling water discharge line L14 , and one end of the gas line L24 is communicated with the siphon part 81 , and the other end of the cooling water pit 40 . Although it communicated with the gas phase part 72, it is not limited to this structure. 3 : is a schematic block diagram which shows the modified example of the fuel gas cooling system of this embodiment.

In the modification of the fuel gas cooling system of this embodiment, as shown in FIG. 3, the fuel gas supply line L11 is provided with the electric dust collector 37. As shown in FIG. The electrostatic precipitator 37 is configured such that a dust collecting electrode 94 is disposed in a housing 93 having an inlet 91 and an outlet 92 . Moreover, in the electrostatic precipitator 37 , a plurality of spray nozzles 95 of washing water for removing foreign matter adhering to the dust collecting electrode 94 are provided above the dust collecting electrode 94 . The washing water pit 96 is disposed below the electrostatic precipitator 37 , and a washing water supply line L31 and a washing water discharge line L32 are provided between the electrostatic precipitator 37 and the washing water pit 96 . is provided. The washing water supply line L31 is provided with a washing water supply pump 97, and by driving the washing water supply pump 97, the washing water in the washing water pit 96 is sprayed from the washing water supply line L31 It is supplied to the nozzle 95, and washing water is sprayed on the dust collecting electrode 94 for cleaning. The washing water washing the dust collecting electrode 94 is returned to the washing water pit 96 from the washing water discharge line L32 by its own weight.

The washing water pit (cooling water storage part) 96 can store a predetermined amount of washing water WW. The washing water pit 96 is composed of a liquid phase part 101 and a gas phase part (inert gas storage part) 102 , the cooling water WW is stored in the liquid phase part 101 , and the gas phase part 102 . An inert gas (eg nitrogen) (N) is charged. In addition, the washing water pit 96 is provided with an inert gas supply line L33 for supplying and bubbling the inert gas N to the liquid portion 101 . The upstream end of the washing water supply line L31 communicates with the liquid phase 101 , and the downstream end of the washing water discharge line L32 communicates with the liquid phase 101 . The cooling water discharge line L14 from the gas cooler 39 (refer to FIG. 2 ) is provided with a siphon part 81 in the middle part, and one end of the gas line (communication path) L24 to the siphon part 81 . The secondary communicates with each other, and the other end of the gas line L24 communicates with the gaseous phase portion 102 of the washing water pit 96 .

In the gas cooler 39 , when the supply of the cooling water CW is stopped, the storage amount of the cooling water CW is lower than the lower limit level, and the inert gas N of the dust collecting electrode 94 and the washing water pit 96 is discharged from the gas line. It is supplied to the siphon part 81 through L24. Then, the discharge of the cooling water CW from the gas cooler 39 through the cooling water discharge line L14 is stopped by the siphon break effect, and a predetermined amount of cooling water is secured in the gas cooler 39 . At this time, the inert gas N supplied to the siphon part 81 penetrates into the gas cooler 39 through the cooling water discharge line L14, but the inert gas N does not contain air. It does not exert a bad influence on the dust collector 37 or the combustor 22.

Thus, in the fuel gas cooling system of this embodiment, the gas cooler 39 cooled by making the cooling water CW contact fuel gas (compressed fuel gas FC), and the cooling water stored in the gas cooler 39 . A cooling water discharge line L14 for discharging (CW), a siphon unit 81 provided in the cooling water discharge line L14, and a gaseous phase portion 72 of the cooling water pit 40 as an inert gas storage unit for storing an inert gas ) and a gas line L24 in which one end communicates with the siphon unit 81 and the other end communicates with the gas phase unit 72 are provided.

Therefore, since the siphon part 81 is in communication with the gas phase part 72 of the cooling water pit 40 by the gas line L24, when oxygen in the air enters the gas cooler 39 and mixes with the fuel gas There is no such thing, and reliability can be improved by securing safety.

In the fuel gas cooling system of this embodiment, the gaseous phase part 72 of the cooling water pit 40 as an inert gas storage part is hold|maintained at the static pressure higher than atmospheric|atmosphere. Accordingly, when the supply of the cooling water CW to the gas cooler 39 is stopped and the storage amount of the cooling water CW in the hopper 54 of the gas cooler 39 decreases, the inert gas N of the gaseous phase part 72 ) is appropriately supplied to the siphon unit 81 from the gas line L24 , and the discharge of the cooling water CW from the gas cooler 39 can be stopped.

In the fuel gas cooling system of the present embodiment, the gas phase portion 72 of the cooling water pit 40 that stores the cooling water CW discharged by the cooling water discharge line L14 is filled with an inert gas N, or The gas phase portion 72 of the cooling water pit 40 is filled with an inert gas (N) in the gas phase portion of the cooling water pit of the electrostatic precipitator 37 , and the other end of the gas line L24 having one end communicating with the siphon portion 81 is connected to the gas phase portion 72 of the cooling water pit 40 . ), it is not necessary to separately provide an inert gas storage part, and the enlargement of an installation can be suppressed.

Moreover, in the gas turbine plant of this embodiment, the gas turbine 11 which has the compressor 21, the combustor 22, and the turbine 23, and fuel gas (compressed fuel gas (FC) supplied to the combustor 22) )) of the fuel gas cooling system is provided.

Accordingly, the fuel gas is cooled by contacting the cooling water CW by the gas cooler 39 , and is supplied to the combustor 22 of the gas turbine 11 through the fuel gas supply line L3 to be combusted. On the other hand, after cooling the fuel gas, the cooling water CW is stored in the hopper 54 of the gas cooler 39 and then discharged from the cooling water discharge line L14 to the outside. At this time, since the siphon part 81 communicates with the gas phase part 72 of the cooling water pit 40 by the gas line L24, when oxygen in the air enters the gas cooler 39 and mixes with the fuel gas There is no fuel gas, and the fuel gas does not adversely affect the electric dust collector 37 or the combustor 22 arranged in the fuel gas supply line L3, so that safety can be secured and reliability can be improved.

In addition, in the above-described embodiment, the other end of the gas line L24, one end of which communicates with the siphon portion 81, is connected to the gas phase portion 72 of the cooling water pit 40 in the gas cooler 39, or, Although it communicates with the gas phase part of the cooling water pit in the electrostatic precipitator 37, you may provide the inert gas storage part exclusively for communicating with the other end of the gas line L24 which communicates with the siphon part 81 separately.

Moreover, in the above-mentioned embodiment, although the fuel gas cooling system of this invention was demonstrated as what compresses the blast furnace gas BFG as fuel gas, you may apply to cooling other fuel gas.

Moreover, in the above-mentioned embodiment, although the gas turbine plant of this invention was applied to the combined cycle plant 10 and demonstrated, it does not have the heat recovery boiler 12 or the steam turbine 13, but has the gas turbine 11 It is good also as a gas turbine plant.

10 Combine Cycle Plant
11 gas turbine
12 Heat Recovery Boiler
13 steam turbine
14 generator
21 Compressor
22 burner
23 turbine
24 rotor
27 turbine
31 gas compressor
32 turbine
36 on-off valve
37 electrostatic precipitator
38 bypass valve
39 gas cooler
40 Coolant Feet (Coolant Reservoir)
41 coolant supply pump
51 housing
52 headers
53 spray nozzle
54 Hopper
71 liquid part
72 Gas phase (inert gas storage)
81 siphon part
82 first vertical part
83 2nd vertical part
84 horizontal
93 housing
94 Dust Collecting Electrode
95 spray nozzle
96 wash water feet (wash water reservoir)
97 Washing water supply pump
101 liquid part
102 Gas phase part (inert gas storage part)
L13 coolant supply line
L14 coolant drain line (drain path)
L21 coolant line
L22 inert gas supply line
L23 gas exhaust line
L24 gas line (communication path)
L31 Washing Water Supply Line
L32 Rinsing Water Discharge Line
L33 Inert Gas Supply Line
A air
AC compressed air
CO carbon monoxide
CW coolant
F fuel gas
FC compressed fuel gas
FG combustion gas
EG exhaust gas
N inert gas
S steam
W revenge

Claims (5)

A gas cooler for cooling by contacting the fuel gas with coolant;
a discharge path for discharging the cooling water stored in the gas cooler;
a siphon unit provided in the discharge path;
an inert gas storage unit for storing the inert gas;
and a communication path having one end communicating with the siphon unit and the other end communicating with the inert gas storage unit. The method according to claim 1,
The fuel gas cooling system, characterized in that the inert gas storage unit is maintained at a static pressure higher than atmospheric pressure. The method according to claim 1,
A cooling water storage unit for storing the cooling water discharged by the discharge path is provided, and the inert gas storage unit is provided in the cooling water storage unit. The method according to claim 1,
A wet electrostatic precipitator for removing foreign substances contained in the fuel gas cooled by the gas cooler is provided, a washing water reservoir is provided in the wet electrostatic precipitator, and the inert gas reservoir is provided in the washing water reservoir fuel gas cooling system. a gas turbine having a compressor, a combustor and a turbine;
The fuel gas cooling system in any one of Claims 1-4 which cools the fuel supplied to the said combustor, The gas turbine plant characterized by the above-mentioned.

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