KR20180078049A - WASTE HEAT RECOVERY device and SYSTEM AND COMBINED CYCLE POWER PLANT - Google Patents

Abstract

The present invention provides a waste heat recovery device, a system thereof, and a combined power plant including the same. According to the present invention, a waste heat recovery system of a combined power plant comprises a gas compressor to compress a fuel gas and a combustor to receive the compressed fuel gas from the gas compressor. The waste heat recovery system comprises: a gas supply line connected to the rear end of the compressor and the front end of the combustor to supply the compressed fuel gas to the combustor from the gas compressor; a bypass line branched from the gas sup line and connected to the front end of the gas compressor to circulate a part of the fuel gas discharged from the gas compressor; and a waste heat recovery device installed on the bypass line, receiving inflow water therein, and using waste heat of the fuel gas of high temperature passing through the bypass line to produce steam.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waste heat recovery apparatus, a waste heat recovery system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waste heat recovery apparatus, a waste heat recovery system, and a combined power generation plant including the same, and more particularly to a waste heat recovery apparatus, a waste heat recovery system, .

Major facilities of the combined power plant include gas compressors, gas turbines, steam turbines, HRSGs, and condensers. Here, the fuel can be supplied to the gas turbine by the fuel system including the gas compressor.

2 shows a schematic diagram of the fuel system 20 and the gas turbine 30 of the conventional combined power generation plant 10.

Referring to FIG. 2, the fuel system 20 of a general combined-cycle power generation system includes a gas mixer in which a fuel gas is mixed, an electrostatic precipitator 25 for removing air pollutants and organic matter, a gas compressor (21). Here, the high-temperature, high-pressure fuel compressed through the gas compressor 21 is bypassed to prevent the surge of the gas compressor 21 and to control the amount of heat input to the combustor 33, 21).

Since the fuel gas circulating through the bypass line 90 is in a high-temperature and high-pressure state, it must be cooled to a certain temperature (about 40 ° C) or less to be fed back to the gas compressor 21. This is to limit the volumetric flow rate of the fuel gas supplied to the fuel supply line 70 through the bypass line 90 and to prevent the high temperature corrosion of the gas compressor 21. However, in the process of cooling the fuel gas passing through the bypass line 90, a large amount of waste heat (about 3.6 Gcal / h or so) may be generated, thereby causing energy loss of the combined power generation plant 10 there is a problem.

SUMMARY OF THE INVENTION The present invention is conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a waste heat recovery apparatus, a waste heat recovery system, and a system for recovering waste heat of a fuel gas bypassed by a waste heat recovery apparatus, And to provide a combined power generation plant including the power plant.

The present invention also provides a waste heat recovery device for supplying steam generated by waste heat recovered through a waste heat recovery device to a steam turbine to increase the power generation output of the steam turbine, a waste heat recovery system, and a combined- .

It is another object of the present invention to provide a waste heat recovery system and waste heat recovery system that further reduce the power of the cooling pump for cooling the fuel gas in the bypass line and improve the energy efficiency of the entire combined- And to provide a combined power generation plant.

In order to achieve the above object, a waste heat recovering apparatus according to the present invention is a waste heat recovering apparatus for a combined cycle power plant including a gas compressor for compressing fuel gas and a combustor for receiving the fuel gas compressed from the gas compressor And a bypass line connected to a downstream end of the gas compressor and a gas supply line connected to a front end of the combustor, the inflow water flowing into the bypass line, the waste heat of the high-temperature fuel gas passing through the bypass line Steam can be produced.

According to another aspect of the present invention, there is provided a waste heat recovery system for a combined cycle power plant, comprising: a gas compressor for compressing a fuel gas; and a combustor for receiving the compressed fuel gas from the gas compressor, A gas supply line connected to a downstream end of the gas compressor and to a front end of the combustor for supplying the compressed fuel gas from the gas compressor to the combustor; A bypass line branched from the gas supply line and connected to a front end of the gas compressor; and a bypass line disposed on the bypass line, the inflow water flowing into the bypass line, And a waste heat recovery device for producing steam using waste heat.

According to another aspect of the present invention, there is provided a combined-cycle power generation plant having a waste heat recovery system, comprising: a gas compressor for compressing a fuel gas to be supplied; an operation unit for operating the fuel gas supplied from the gas compressor, A waste heat recovery system disposed between the gas compressor and the gas turbine to recover waste heat of the fuel gas discharged from the gas compressor; a waste heat recovery system including a power turbine, Wherein the waste heat recovery system includes: a gas supply line for supplying the fuel gas compressed by the gas compressor to the combustor; and a gas supply line branched from the gas supply line and connected to the front end of the gas compressor A bypass line provided on the bypass line and connected to the bypass line, Using the waste heat of the gas exit may comprise a heat recovery unit to produce steam.

In order to achieve the above object, a waste heat recovering apparatus according to the present invention is a waste heat recovering apparatus for a combined cycle power plant including a gas compressor for compressing fuel gas and a combustor for receiving the fuel gas compressed from the gas compressor And a bypass line connected to a downstream end of the gas compressor and a gas supply line connected to a front end of the combustor, the inflow water flowing into the bypass line, the waste heat of the high-temperature fuel gas passing through the bypass line Steam can be produced.

According to another aspect of the present invention, there is provided a waste heat recovery system for a combined cycle power plant, comprising: a gas compressor for compressing a fuel gas; and a combustor for receiving the compressed fuel gas from the gas compressor, A gas supply line connected to a downstream end of the gas compressor and to a front end of the combustor for supplying the compressed fuel gas from the gas compressor to the combustor; A bypass line branched from the gas supply line and connected to a front end of the gas compressor; and a bypass line disposed on the bypass line, the inflow water flowing into the bypass line, And a waste heat recovery device for producing steam using waste heat.

According to another aspect of the present invention, there is provided a combined-cycle power generation plant having a waste heat recovery system, comprising: a gas compressor for compressing a fuel gas to be supplied; an operation unit for operating the fuel gas supplied from the gas compressor, A waste heat recovery system disposed between the gas compressor and the gas turbine to recover waste heat of the fuel gas discharged from the gas compressor; a waste heat recovery system including a power turbine, Wherein the waste heat recovery system includes: a gas supply line for supplying the fuel gas compressed by the gas compressor to the combustor; and a gas supply line branched from the gas supply line and connected to the front end of the gas compressor A bypass line provided on the bypass line and connected to the bypass line, Using the waste heat of the gas exit may comprise a heat recovery unit to produce steam.

1 is a block diagram schematically showing a combined-cycle power plant having a waste heat recovery system according to an embodiment of the present invention.
2 is a flow diagram of a fuel system and a gas turbine of a conventional combined power generation plant.
3 is a schematic diagram of a fuel system and a gas turbine showing a waste heat recovery system according to an embodiment of the present invention.

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

First, the embodiments described below are embodiments suitable for understanding the technical characteristics of the waste heat recovery apparatus, the waste heat recovery system, and the combined power generation plant including the waste heat recovery apparatus of the present invention. However, the technical features of the present invention are not limited by the embodiments to which the present invention is applied or explained in the following embodiments, and various modifications are possible within the technical scope of the present invention.

1 and 3, a combined power generation plant 10 having a waste heat recovery system according to an embodiment of the present invention includes a gas compressor 21, a gas turbine 30, A recovery system, and a generator. Further, it may further include an arrangement recovery boiler 60, a steam turbine 40, and a condenser 50.

The gas compressor (21) can compress the supplied fuel gas. Here, the fuel gas supplied through the gas compressor 21 may be a byproduct gas generated in the blast furnace of the steelworks. For example, COG (coke oven gas), blast furnace gas (BFG), fine off gas (FOG), and LDG (Linz-Donawitz gas) can be used. However, the fuel gas supplied to the gas compressor 21 is not limited to the above-mentioned by-product gas, and various fuels such as natural gas may be used.

The gas compressor 21 may serve to supply the fuel gas such as by-product gas to the combustor 33 of the gas turbine 30 at a predetermined pressure or higher.

The gas turbine 30 can operate using the fuel gas supplied from the gas compressor 21. The gas turbine 30 includes an air compressor 31, a turbine 34, and a combustor 33. The combustor 33 can receive the high-temperature, high-pressure fuel gas compressed through the gas compressor 21 through the gas supply line 80. This fuel gas can be burned by the high-temperature high-pressure compressed air supplied from the air compressor 31 to operate the turbine 34. The reference numeral 32 is an air supply source.

The waste heat recovery system may be provided between the gas compressor 21 and the gas turbine 30 so as to recover the waste heat of the fuel gas discharged from the gas compressor 21.

The heat recovery steam generator (HRSG) 60 may generate steam using the arrangement of the exhaust gas generated from the gas turbine 30. Specifically, the heat energy discharged when the gas turbine 30 is operated can be recovered, and the steam can be supplied to the steam turbine 40 again with high-temperature and high-pressure steam. The batch recovery boiler 60 includes a high pressure superheater 61 supplied with a high temperature gas from the gas turbine 30 and a low pressure superheater 62 supplied with steam discharged from the high pressure superheater 61 .

The steam turbine (40) can be operated by steam generated in the batch recovery boiler (60). Specifically, the steam turbine 40 can be operated by producing high-temperature, high-pressure steam as heat recovered through the batch recovery boiler 60. The steam turbine 40 includes a high-pressure cylinder 41 that receives high-pressure steam from the high-pressure superheater 61 and a high-pressure cylinder 41 that is supplied with relatively low-pressure steam from the low- And may include a cylinder 42. However, the configuration of the steam turbine 40 is not limited to the illustrated embodiment, but can be modified.

The condenser 50 can condense the steam used in the steam turbine 40. That is, the steam discharged from the steam turbine 40 is cooled and condensed by heat exchange, so that condensed water can be generated.

The generator can be generated by the power of the gas turbine 30 and the steam turbine 40. That is, mechanical energy by the gas turbine 30 and the steam turbine 40 can be converted into electrical energy.

A waste heat recovery apparatus 100 according to an embodiment of the present invention is installed on a bypass line 90 branched from a gas supply line 80 connected to a rear end of a gas compressor 21 and a front end of a combustor 33 .

Hereinafter, the waste heat recovery apparatus 100 and the waste heat recovery system will be described in detail with reference to FIG. 3 is a schematic diagram of a fuel system 20 and a gas turbine 30 showing a waste heat recovery system in accordance with one embodiment of the present invention.

3, the waste heat recovery system according to the present invention includes a gas supply line 80 and a bypass line 90, and the waste heat recovery apparatus 100 is installed on the bypass line 90 .

The gas supply line 80 is connected to the downstream end of the gas compressor 21 and the upstream end of the combustor 33 so that the compressed fuel gas can be supplied from the gas compressor 21 to the combustor 33. The fuel gas passing through the gas supply line 80 is in a state of high temperature and high pressure, for example, the temperature may be about 360 DEG C, and the pressure may be about 15ata. However, the temperature and the pressure of the fuel gas flowing through the gas supply line 80 are not limited thereto, and may be variously changed depending on the operating environment.

The bypass line 90 may be branched at the gas supply line 80 and connected to the front end of the gas compressor 21 so as to circulate a part of the fuel gas discharged from the gas compressor 21. [ Specifically, the bypass line 90 is connected to the fuel supply line 70 so that a part (about 10%) of the fuel gas discharged from the gas compressor 21 can flow in and bypass the bypassed fuel gas And then supplied to the gas compressor 21 again. This is to prevent the surge of the gas compressor 21 and to control the amount of heat input to the combustor 33.

Since the fuel gas circulating through the bypass line 90 is in a high-temperature and high-pressure state, it must be cooled to a certain temperature (about 40 ° C) or less to be fed back to the gas compressor 21. This is to limit the volumetric flow rate of the fuel gas supplied to the fuel supply line 70 through the bypass line 90 and to prevent the high temperature corrosion of the gas compressor 21. However, in the process of cooling the fuel gas passing through the bypass line 90, a large amount of waste heat (about 3.6 Gcal / h or so) may be generated, thereby causing energy loss of the combined power generation plant 10 there is a problem.

In the waste heat recovery system according to the present invention, the waste heat recovery apparatus 100 may be installed on the bypass line 90 to recover waste heat generated from the high-temperature fuel gas to further produce steam.

Specifically, the waste heat recovery apparatus 100 can generate steam by using the waste heat of the high-temperature fuel gas flowing into the bypass line 90 through which the influent water flows.

Here, the inflow water flowing into the waste heat recovery apparatus 100 may be condensed water condensed in the condenser 50, and the steam produced and discharged from the waste heat recovery apparatus 100 may be supplied to the arrangement recovery boiler 60. At this time, the steam to be discharged may be supplied to the low pressure superheater 62 of the arrangement recovery boiler 60 in consideration of the temperature and pressure conditions, but it is not limited thereto and may be changed according to the operating environment.

As described above, according to the waste heat recovery system of the present invention, the waste heat of the fuel gas bypassed by the waste heat recovery apparatus 100 can be recovered to minimize the energy loss of the combined-cycle power plant 10.

The additional steam produced by the waste heat recovered through the waste heat recovery device 100 is supplied to the steam turbine 40 through the arrangement recovery boiler 60 to increase the power generation output of the steam turbine 40 Can be obtained.

Referring to FIG. 3, the fuel system 20 may further include a gas mixer 23 and an electrostatic precipitator 25 (electrostatic precipitator).

The gas mixer 23 may be connected to the fuel supply line 70 at the upstream end of the gas compressor 21 and may mix two or more byproduct gases introduced into the gas compressor 21. The electrostatic precipitator 25 is provided on the fuel supply line 70 connecting the gas mixer 23 and the gas compressor 21 to remove air pollutants and organic substances from the by- can do.

Specifically, the waste heat recovery system may further include a flow control valve 91. The flow rate control valve 91 is provided on the bypass line 90 so as to regulate the flow rate of the fuel gas bypassing the bypass line 90 in the gas supply line 80, As shown in FIG. That is, the waste heat recovery apparatus 100 is provided at the rear end of the flow control valve 91, so that a proper amount of the fuel gas can be supplied to the waste heat recovery apparatus 100.

The waste heat recovery apparatus 100 may include an inlet 120, a heat exchange unit 110, and a discharge unit 130.

The inflow section 120 can inflow inflow water. There is no limitation on the inflow water flowing into the inflow section 120, but the condensate condensed in the condenser 50 can be introduced, for example.

The heat exchange unit 110 can exchange the inflow water introduced from the inflow section 120 with the fuel gas passing through the bypass line 90. Through this heat exchange process, steam can be generated from the inflow water.

The discharge unit 130 can discharge steam generated by the heat exchange of the heat exchange unit 110. Such steam may be discharged in a variety of ways, but is preferably supplied to the batch recovery boiler 60 and may serve as additional steam to operate the steam turbine 40.

The waste heat recovery system according to the present invention may further include a cooling unit 200. The cooling unit 200 may include a cooling device and a cooling pump 210. [

The cooling device is installed on the bypass line 90 and is installed at the rear end of the waste heat recovery apparatus 100 to cool the fuel gas that has passed through the waste heat recovery apparatus 100. The cooling pump 210 can supply cooling water to the cooling device.

Specifically, the cooling water supplied by the cooling pump 210 is heat-exchanged with the fuel gas that has passed through the waste heat recovery apparatus 100, so that the fuel gas can be cooled. At this time, depending on the amount of cooling water supplied by the cooling pump 210, the degree of cooling of the fuel gas can be determined.

At this time, since part of the waste heat (about 1.9 Gcal / h) can be recovered by the waste heat recovery apparatus 100, waste heat generated by cooling in the cooling unit 200 is reduced (for example, 3.6 Gcal / To 1.7 Gcal / h). However, the amount of waste heat recovered by the waste heat recovery apparatus 100 is not limited to that described above.

The waste heat recovery system may further include a temperature measurement unit 300.

The temperature measuring unit 300 may be disposed on the bypass line 90 and may be disposed downstream of the cooling unit 200 to measure the temperature of the fuel gas that has passed through the cooling unit 200.

Specifically, the fuel gas introduced into the bypass line 90 can be reduced in temperature (for example, reduced to 360 ° C to 174 ° C) while passing through the waste heat recovery apparatus 100. The temperature of the fuel gas thus cooled and cooled by the cooling unit 200 may be lower than a predetermined temperature (about 37 DEG C). The temperature measuring unit 300 can measure the temperature of the fuel gas passing through the cooling unit 200 and predict the degree of heat exchange through the waste heat recovering apparatus 100.

In addition, the cooling unit 200 may include an inverter 230 and a control unit 250.

The inverter 230 can control the cooling pump 210 to adjust the flow rate of the cooling water supplied to the cooling device. The control unit 250 can control the inverter 230 based on the temperature received from the temperature measuring unit 300. [

Specifically, the temperature of the fuel gas circulated through the temperature measuring unit 300 can be known, and the controller 250 can control the inverter 230 when the received temperature is lower than a preset temperature So that the flow rate to the cooling pump 210 can be reduced.

Thereby, the cooling pump 210 can be operated so that an appropriate amount of cooling water is introduced into the cooling device, so that the power of the cooling pump 210 required to cool the fuel gas in the bypass line 90 can be further reduced . As a result, the energy efficiency of the entire combined-cycle power generation system can be improved.

As described above, according to the waste heat recovery apparatus, the waste heat recovery system, and the combined-cycle power plant including the same according to the present invention, the waste heat of the fuel gas bypassed by the waste heat recovery apparatus is recovered to minimize the energy loss of the combined- .

Further, according to the present invention, the additional steam produced by the waste heat recovered through the waste heat recovering device can be supplied to the steam turbine, thereby enhancing the power generation output of the steam turbine.

Further, according to the present invention, the power of the cooling pump for cooling the fuel gas in the bypass line can be further reduced, thereby improving the energy efficiency of the entire combined-cycle power generation system.

While the invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And various modifications and changes may be made without departing from the scope of the present invention.

10: Combined cycle power plant 21: Gas compressor
30: gas turbine 33: combustor
40: steam turbine 50: condenser
60: batch recovery boiler 70: fuel supply line
80: gas supply line 90: bypass line
91: Flow control valve 100: Waste heat recovery device
110: heat exchanger 120: inlet
130: discharging part 200: cooling part
210: Cooling pump 230: Inverter
250: control unit 300: temperature measuring unit

Claims (10)

1. A waste heat recovery apparatus for a combined cycle power plant, comprising: a gas compressor for compressing a fuel gas; and a combustor for receiving the fuel gas compressed from the gas compressor,
The bypass line being connected to a downstream end of the combustor and a gas supply line connected to a front end of the combustor, the inflow water being introduced into the bypass line, the steam having a high temperature passing through the bypass line, The waste heat recovery device. 1. A waste heat recovery system for a combined cycle power plant, comprising: a gas compressor for compressing a fuel gas; and a combustor for receiving the fuel gas compressed from the gas compressor,
A gas supply line connected to a downstream end of the gas compressor and a front end of the combustor to supply the compressed fuel gas from the gas compressor to the combustor;
A bypass line branched from the gas supply line and connected to a front end of the gas compressor so as to circulate a part of the fuel gas discharged from the gas compressor; And
And a waste heat recovering device installed on the bypass line to receive inflow water from the waste heat recovery device and to generate steam using waste heat of the high temperature fuel gas passing through the bypass line. 3. The method of claim 2,
Further comprising a flow control valve provided on the bypass line and disposed upstream of the waste heat recovery apparatus so as to regulate the flow rate of the fuel gas bypassing the bypass line in the gas supply line, . 3. The method of claim 2,
In the waste heat recovery device,
An inflow portion into which inflow water flows;
A heat exchange unit for heat-exchanging the inflow water introduced from the inflow section with the fuel gas passing through the bypass line; And
And a discharge section for discharging steam generated by heat exchange of the heat exchange section. The method of claim 3,
A cooling device installed on the bypass line and provided at a rear end of the waste heat recovery device for cooling the fuel gas passed through the waste heat recovery device and a cooling pump for supplying cooling water to the cooling device, Further comprising a cooling section. 6. The method of claim 5,
Further comprising a temperature measuring unit provided on the bypass line and disposed at a downstream end of the cooling unit for measuring a temperature of the fuel gas passed through the cooling unit. The cooling apparatus according to claim 6,
An inverter for controlling the cooling pump to regulate a flow rate of cooling water supplied to the cooling device; And
And a control unit for controlling the inverter based on the temperature received from the temperature measurement unit. A gas compressor for compressing the supplied fuel gas;
A gas turbine that operates using the fuel gas supplied from the gas compressor and includes an air compressor, a turbine, and a combustor;
A waste heat recovery system provided between the gas compressor and the gas turbine to recover waste heat of the fuel gas discharged from the gas compressor; And
And a generator that is powered by the power of the gas turbine,
The waste heat recovery system includes a gas supply line for supplying the fuel gas compressed by the gas compressor to the combustor, a bypass line branched from the gas supply line and connected to a front end of the gas compressor, And a waste heat recovery system installed on the line for producing steam using waste heat of the high-temperature fuel gas passing through the bypass line. 9. The method of claim 8,
An arrangement recovery boiler for generating steam using an arrangement of exhaust gases generated from the gas turbine;
A steam turbine operated by steam generated in the batch recovery boiler; And
Further comprising a condenser for condensing the steam used in the steam turbine,
The waste heat recovering apparatus includes an inlet portion into which condensed water condensed in the condenser flows, a heat exchange portion to heat-exchange the condensed water introduced from the inlet portion with the fuel gas passing through the bypass line, And a discharge unit for discharging steam generated by the steam generator to the batch recovery boiler. 9. The method of claim 8,
The fuel gas supplied to the gas compressor is provided as byproduct gas generated in the blast furnace of a steelworks,
Further comprising a gas mixer for mixing a plurality of said byproduct gases at a front end of said gas compressor.

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