KR101487287B1 - Power Plant - Google Patents

Abstract

An embodiment of the present invention is directed to a fuel cell system including a fuel storage for storing liquefied natural gas, an evaporator for forming a fuel by vaporizing the liquefied natural gas, a gas turbine for producing power by burning the fuel and combustion air, Wherein the combustion air is cooled using the liquefied natural gas.

Description

Power Plant [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power generating device, and more particularly, to a power generating device that uses natural gas as a fuel and uses natural gas to vaporize natural gas.

Combined Cycle Power Plant (Combined Cycle Power Plant) generates electricity by using gas such as natural gas or light oil to operate the gas turbine first, passes the exhaust gas heat from the gas turbine back to the boiler, And the second is to operate the steam turbine to generate electricity.

The gas turbine combined cycle power plant, which uses natural gas as a fuel, generates electricity by supplying the gas turbine with fuel after vaporizing the stored liquefied natural gas (LNG) with a vaporizer and utilizing the waste heat of the exhaust gas Steam is produced and supplied to the steam turbine to improve the power generation efficiency.

Although it is generally used because it is the most economical method to directly use seawater by vaporizing stored liquefied natural gas (LNG), there is a disadvantage that seawater is cooled to a temperature lower than its original temperature and discharged outside, The energy is wasted because it is discharged to the outside without being utilized.

The power generation apparatus according to an embodiment of the present invention is intended to provide a power generation apparatus having a structure capable of preventing seawater from being cooled down to a temperature lower than the original temperature and discharging the seawater to the outside in the process of vaporizing liquefied natural gas, .

According to an aspect of the present invention, there is provided a fuel cell system including: a fuel storage unit for storing liquefied natural gas; an evaporator for forming a fuel by vaporizing the liquefied natural gas; and an evaporator for generating electricity by burning the fuel and combustion air, A power generation apparatus including a gas turbine, wherein the combustion air is cooled using the liquefied natural gas, may be provided.

And a heating medium for exchanging heat with the liquefied natural gas supplied to the evaporator, wherein the heating medium can cool the combustion air.

The evaporator can vaporize the liquefied natural gas using seawater.

The temperature of the seawater may be increased by using the exhaust gas before the seawater is introduced into the evaporator.

A part of the seawater supplied to the evaporator may be bypassed and mixed with the seawater having passed through the evaporator.

An arrangement recovery boiler for absorbing the heat of the exhaust gas, and a steam turbine for generating heat by receiving heat from the arrangement recovery boiler.

The exhaust vapors used in the steam turbine can be heat exchanged with seawater in a condenser.

The embodiment of the present invention forms a structure for circulating the heating medium between the intermediate heat exchanger and the turbine inlet heat exchanger so that a part of the cold discharged in the process of vaporizing the liquefied natural gas is used for cooling the combustion air of the gas turbine, An effect of improving the efficiency of the semiconductor device is generated.

In the embodiment of the present invention, the seawater is heat-exchanged in the condenser before vaporizing the liquefied natural gas while passing through the evaporator, and the temperature of the seawater is changed from the sea to the initial temperature It is possible to minimize the environmental pollution by discharging at substantially similar temperatures.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a cold / hot water collection system of a combined-cycle thermal power generation apparatus according to an embodiment of the present invention. FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the appended drawings illustrate the present invention in order to more easily explain the present invention, and the scope of the present invention is not limited thereto. You will know.

In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

Also, the terms used in the present application are used only to describe certain embodiments and are not intended to limit the present invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

1 is a schematic diagram showing a cold / hot recovery system of a power generation apparatus according to an embodiment of the present invention.

The power generation apparatus according to an embodiment of the present invention includes a gas turbine 100 and a steam turbine 200 and is constructed to generate electricity again from the steam turbine 200 using exhaust gas discharged from the gas turbine 100 .

The gas turbine 100 is supplied with fuel after the liquefied natural gas at a cryogenic temperature is vaporized.

In the vaporizer 320 for vaporizing the liquefied natural gas at a cryogenic temperature, the seawater 400 is passed through and heat exchanges to vaporize the liquefied natural gas to form a fuel.

The steam discharged after the power generation in the steam turbine 200 is heat-exchanged in the condenser 210 and condensed again.

According to the embodiment of the present invention, by using the cryogenic state of the liquefied natural gas supplied to the gas turbine 100, the air supplied to the gas turbine 100 is cooled, and a state of cryogenic temperature (generally -163 ° C) The seawater 400 used in the evaporator 320 for vaporizing the liquefied natural gas is heat-exchanged in the condenser 210 of the steam turbine 200 and then supplied to the evaporator 320 after the preheating.

This is explained in more detail as follows.

The high pressure pump of the fuel storage unit 300 storing the liquefied natural gas supplies the cryogenic liquefied natural gas to the gas turbine 100 through the evaporator 320. In the embodiment of the present invention, An intermediate heat exchanger 330 is formed between the evaporator 320 and a turbine inlet heat exchanger 110 is formed in the combustion air inlet of the gas turbine 100.

A closed loop pipe 120 is formed between the intermediate heat exchanger 330 and the turbine inlet heat exchanger 110 and a structure for circulating a heating medium such as glycol in the closed loop pipe 120 is formed.

Heating medium (heat medium) is a generic name of materials used for heat transfer.

Such a heating medium generally circulates the boiler and heats the object to be heated by latent heat of the saturated vapor of the heating medium. The condensed condensed material is discharged as latent heat, so that the heating medium is used as a core element of the indirect heating process . However, the narrow meaning of the heating medium refers to a medium capable of transporting heat at a high temperature of about 300 to 400 DEG C even at a low pressure. For example, glycol, oil or mercury may be used as the heating medium.

Meanwhile, the embodiment of the present invention forms a structure for circulating the heating medium between the intermediate heat exchanger 330 and the turbine inlet heat exchanger 110 so that a part of the cold heat discharged in the course of vaporizing the liquefied natural gas is supplied to the gas turbine 100 ) Of the gas turbine (100) is used for cooling the combustion air of the gas turbine (100).

The reason for using the indirect heat exchange method in which the heat medium such as the glycol is circulated without directly exchanging the heat between the combustion air and the cryogenic liquefied natural gas is that in the case of direct heat exchange between the combustion air and the cryogenic liquefied natural gas, Freezing of water and leakage of liquefied natural gas can cause explosion and fire.

The gas turbine 100 into which the combustion air flows is, for example, a rotary type heat engine that operates the turbine with high-temperature and high-pressure combustion gases. Generally, the gas turbine 100 comprises a compressor, a combustor, and a turbine. The gas turbine 100 compresses the air with a compressor and directs the compressed air to the combustion chamber, where the fuel is dispersed and combusted. The high-temperature and high-pressure gas generated at this time is blown into the turbine while expanding to rotate the turbine.

Meanwhile, the heat generated in the process of exhausting exhaust gas by operating the gas turbine 100 is converted into high-pressure and low-pressure steam 132, 134 through heat exchange in a heat recovery steam generator (HRSG) .

Since the HRSG 130 has a large amount of energy at a high temperature exhaust gas of about 650 ° C., which is discharged after combustion of the gas turbine 100, a considerable loss occurs when the exhaust gas is discharged into the atmosphere. Therefore, It is a device that recovers energy that is thrown away into gas. The high temperature exhaust gas discharged from the gas turbine 100 is heat-exchanged while passing through the batch recovery boiler 130 to generate a high pressure steam 132 and a low pressure steam 134.

The generated high-pressure steam 132 flows into the steam turbine 200 and is used to drive the steam turbine 200.

The generated low pressure steam 134 is used to drive the steam turbine 200 while the portion 134a is introduced into the steam turbine 200 while the other portion 134b is used to drive the low pressure feedwater heater 220, and the other remaining portion 134c is introduced into an air separator 230. [

A portion 134a of the low pressure steam 134 flowing into the steam turbine 200 is equal to a steam amount obtained by subtracting the amount of the high pressure steam 132 flowing from the steam amount accommodable in the steam turbine 200. [

The other portion 134b of the low pressure steam 134 passes through the low pressure feedwater heater 220 and releases heat and flows into the condenser 210 under the steam turbine 200. [

The remaining portion 134c of the low pressure steam 134 flows into the air separator 230 and is coupled to the condensed water passing through the low pressure feedwater heater 220 and is transferred to the high pressure condensing pump 240.

Generally, an air separator (deaerator, air separator) is an air separator installed to remove water from the boiler feedwater if it contains oxygen, because the water line and boiler are corroded, and it is also called a deaerator.

In the embodiment of the present invention, the air separator 230 separates the remaining portion 134c of the low-pressure steam 134 from the oxygen contained in the condensed water.

On the other hand, a condenser 210 is formed below the steam turbine 200.

The exhaust steam used in the steam turbine 200 is condensed while being exchanged with the seawater 400 that is moved through the seawater pipe in the condenser 210 to be converted into condensed water and is supplied to the LP low- Heat exchanged with a part 134b and passed through an air separator 230 and a high pressure condencer pump 240 to the batch recovery boiler 130. [

The condensed water transferred to the batch recovery boiler 130 is heat-exchanged and divided into a high-pressure steam 132 and a low-pressure steam 134, and then is returned to the steam turbine 200.

On the other hand, the seawater 400 functions to vaporize the liquefied natural gas while passing through the evaporator 320 in a state where the temperature of the seawater 400 is exchanged with the heat of the condenser 210, thereby discharging the seawater 400 to the sea in a state where the temperature is lowered.

Since the seawater 400 passes through the evaporator 320 and is heat-exchanged in the condenser 210 before the liquefied natural gas is vaporized, the temperature discharged to the sea first flows into the condenser 210 The effect of minimizing environmental pollution is generated.

In the embodiment of the present invention, the bypass passage 420 connected to the sea water 400 passing through the evaporator 320 bypasses the seawater 400 without passing through the condenser 210 and the evaporator 320, .

The sea water 400, which is moved to the bypass channel 420, passes through the condenser 210 and is in a state of rising temperature.

Therefore, in the embodiment of the present invention, when the temperature of the sea water 400 passing through the evaporator 320 is significantly lower than the temperature of the first sea water 400, the sea water 400 combined with the sea water 400 moved to the bypass channel 420, As shown in FIG.

In the embodiment of the present invention, although the temperature of the seawater 400 drops through the evaporator 320 due to the heat exchange process of the seawater 400 in the condenser 210 and the process of passing through the bypass flow path 420 And the temperature of the seawater 400 is discharged at a temperature substantially similar to the initial temperature at the time of entering the power generation apparatus from the ocean.

The bypass flow path 420 is provided with a solenoid valve so that the amount of the seawater 400 passing through the bypass flow path 420 can be appropriately adjusted.

It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is obvious to them. Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: gas turbine 110: turbine inlet heat exchanger
120: closed loop tube 200: steam turbine
220: low pressure feedwater heater 230: separator
320: Evaporator 400: Seawater
420: Bypass passage

Claims (7)

A fuel storage portion for storing liquefied natural gas; An evaporator for vaporizing the liquefied natural gas to form a fuel; A gas turbine that burns the fuel and combustion air to produce electric power and discharges exhaust gas; And a steam turbine that receives heat from an arrangement recovery boiler that absorbs the heat of the exhaust gas to generate steam and discharges the exhaust steam,
Wherein the combustion air is heat exchanged with the liquefied natural gas in an intermediate heat exchanger connected to the evaporator through the separate heating medium circulated through the intermediate heat exchanger,
Wherein the discharge steam is heat exchanged with the liquefied natural gas at a condenser connected to the evaporator, the discharge steam exchanges heat with the liquefied natural gas through seawater circulated through the condenser,
Wherein a part of the seawater supplied to the evaporator through the condenser is bypassed and mixed with the seawater having passed through the evaporator. delete delete The method according to claim 1,
And the temperature of the seawater is increased by using the exhaust gas before the seawater is introduced into the evaporator. delete delete delete

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