KR102473756B1 - Combined power plant and operating method of the same - Google Patents

Abstract

A combined power generation system according to an aspect of the present invention includes a gas turbine generating rotational force by burning fuel, a high pressure part, a medium pressure part, and a low pressure part having different pressure levels and heating feed water using combustion gas discharged from the gas turbine. Heat recovery boiler, a fuel preheater that heats the fuel supplied to the gas turbine and has a primary heating unit and a secondary heating unit, a high-pressure water supply pipe connected to the high-pressure unit and supplying high-pressure water to the secondary heating unit, the secondary heating A water delivery pipe connecting the unit and the primary heating unit to supply water discharged from the secondary heating unit to the primary heating unit, a water supply control tube connected to the intermediate pressure unit and supplying medium pressure water to the water supply delivery pipe, and an intermediate control valve installed between the primary heating unit and the secondary heating unit to control the flow rate of the high-pressure water supply flowing into the secondary heating unit and controlling the flow rate of the medium-pressure water supply according to the flow rate of the high-pressure water supply. can

Description

Combined power generation system and driving method of the combined power generation system {COMBINED POWER PLANT AND OPERATING METHOD OF THE SAME}

The present invention relates to a combined power generation system and a driving method of the combined power generation system. More specifically, the present invention relates to a combined power generation system having a gas turbine and a fuel preheater and a method of driving the combined power generation system.

A combined power generation system is a power generation system configured by combining a gas turbine and a steam turbine with high efficiency to guide high-temperature exhaust gas from the gas turbine to a heat recovery boiler (HRSG) and generate steam by using thermal energy retained in the exhaust gas. This steam enables power generation by the steam turbine and can be combined with the power generated by the gas turbine to improve the thermal efficiency equivalent to the thermal energy retained in the exhaust gas compared to stand-alone power production by the gas turbine. .

A gas turbine is a power engine that mixes and burns compressed air compressed by a compressor with fuel, and rotates the turbine with high-temperature gas generated by combustion. Gas turbines are used to drive generators, aircraft, ships and trains.

In order to improve the efficiency of a gas turbine, it is necessary to preheat fuel introduced into the gas turbine. The temperature of the gas turbine increases as the fuel is preheated to a high temperature, but when the fuel is overheated, a problem of carbonization due to thermal decomposition may occur during the process of preheating the fuel.

Based on the technical background as described above, the present invention provides a combined power generation system capable of efficiently preheating fuel supplied to a gas turbine and a driving method of the combined power generation system.

A combined power generation system according to an aspect of the present invention includes a gas turbine generating rotational force by burning fuel, a high pressure part, a medium pressure part, and a low pressure part having different pressure levels and heating feed water using combustion gas discharged from the gas turbine. Heat recovery boiler, a fuel preheater that heats the fuel supplied to the gas turbine and has a primary heating unit and a secondary heating unit, a high-pressure water supply pipe connected to the high-pressure unit and supplying high-pressure water to the secondary heating unit, the secondary heating A water delivery pipe connecting the unit and the primary heating unit to supply water discharged from the secondary heating unit to the primary heating unit, a water supply control tube connected to the intermediate pressure unit and supplying medium pressure water to the water supply delivery pipe, and an intermediate control valve installed between the primary heating unit and the secondary heating unit to control the flow rate of the high-pressure water supply flowing into the secondary heating unit and controlling the flow rate of the medium-pressure water supply according to the flow rate of the high-pressure water supply. can

According to one aspect of the present invention, the middle pressure unit includes a middle pressure pump that pressurizes and moves water and a middle pressure economizer that receives water from the middle pressure pump and heats the water, and the water supply control pipe includes the middle pressure pump and the middle pressure economizer. Water may be supplied from the medium pressure pump by being connected therebetween.

The high-pressure water supply pipe according to an aspect of the present invention may supply liquid water to the secondary heating unit.

According to one aspect of the present invention, the high-pressure unit includes a high-pressure economizer for heating feed water, a high-pressure drum for storing the feed water heated in the high-pressure economizer, and a high-pressure evaporator for heating water in the high-pressure drum and converting it into steam, The high-pressure water supply pipe may be connected between the high-pressure economizer and the high-pressure drum to receive water heated by the high-pressure economizer.

The intermediate control valve according to one aspect of the present invention may be located between a connection part where the water supply control pipe and the water supply delivery pipe are connected and the secondary heating part.

In the combined power generation system according to an aspect of the present invention, a feed water recovery pipe for transferring the feed water discharged from the primary heating unit to the heat recovery boiler and a feed water recovery pipe are installed to control the flow rate of the feed water discharged from the primary heating unit. It may further include a downstream control valve that

Excess high-pressure water supplied from the secondary heating unit may be supplied to the medium-pressure economizer through the water supply control pipe by the downstream control valve according to an aspect of the present invention.

Combined power generation system according to an aspect of the present invention connects the upstream of the primary heating unit and the downstream of the secondary heating unit, bypasses the primary heating unit and the secondary heating unit, and supplies fuel downstream of the secondary heating unit. A bypass pipe for moving may be further included.

The combined power generation system according to an aspect of the present invention further includes a bypass pipe connecting upstream of the primary heating unit and upstream of the secondary heating unit to bypass the primary heating unit and move fuel to the secondary heating unit. can do.

A fuel control valve for controlling the flow rate of fuel moving through the bypass pipe may be installed in the bypass pipe according to one aspect of the present invention.

The primary heating unit and the secondary heating unit according to an aspect of the present invention may have the same capacity.

An intermediate pressure control valve for adjusting the flow rate of the water supplied from the water supply control pipe to the water delivery pipe may be installed in the water supply control pipe according to an aspect of the present invention.

A gas turbine, a steam turbine, a heat recovery boiler, and a fuel preheater having a primary heating unit and a secondary heating unit for preheating fuel, wherein the heat recovery boiler includes a low pressure unit, a medium pressure unit, and a high pressure unit according to an aspect of the present invention. The driving method of the combined power generation system including a mixture of the water discharged from the secondary heating unit and the water supplied from the intermediate pressure unit, supplying the mixture to the primary heating unit, and supplying the water heated by the high pressure unit to the secondary heating unit. A fuel preheating step, a fuel temperature determination step of measuring the temperature of the fuel discharged from the primary heating unit and the temperature of the fuel discharged from the secondary heating unit and comparing them with a reference temperature, and A valve control step of controlling the temperature of the fuel by adjusting a downstream control valve that controls the flow rate of the feed water and an intermediate control valve that controls the movement of the feed water between the primary heating unit and the secondary heating unit.

In the fuel preheating step according to an aspect of the present invention, the water supplied through the water supply control pipe connected between the intermediate pressure pump and the intermediate pressure economizer of the intermediate pressure unit is mixed with the water discharged from the secondary heating unit to be supplied to the primary heating unit. can supply

In the fuel preheating step according to an aspect of the present invention, water may be supplied to the secondary heating unit through a high-pressure water supply pipe connected between the high-pressure economizer and the high-pressure drum of the high-pressure unit.

The valve control step according to an aspect of the present invention increases the opening of the downstream control valve when the temperature of the fuel discharged from the primary heating unit is lower than a preset first reference temperature, and in the primary heating unit When the temperature of the discharged fuel is higher than the first reference temperature, the opening of the downstream control valve is reduced, and when the temperature of the fuel discharged from the secondary heating unit is lower than the preset second reference temperature, the intermediate control valve The opening degree may be increased, and the opening degree of the intermediate control valve may be decreased when the temperature of the fuel discharged from the secondary heating unit is higher than the second reference temperature.

In the valve control step according to an aspect of the present invention, the temperature of the fuel is controlled by adjusting a fuel control valve installed in a bypass pipe for bypassing the primary heating unit and the secondary heating unit and supplying fuel to the downstream side of the secondary heating unit. Adjusting, but reducing the opening of the fuel control valve when the temperature of the fuel discharged from the secondary heating unit is lower than the preset second reference temperature, and opening the intermediate control valve when the fuel control valve is closed degree can be increased.

The valve control step according to an aspect of the present invention increases the opening degree of the fuel control valve when the temperature of the fuel discharged from the secondary heating unit is higher than the second reference temperature, and the fuel control valve is fully opened. If so, the opening degree of the intermediate control valve may be reduced.

In the valve control step according to one aspect of the present invention, the temperature of the fuel is adjusted by adjusting the intermediate pressure control valve that controls the flow rate of the feedwater supplied from the intermediate pressure unit, and the temperature of the fuel discharged from the primary heating unit is set to When the temperature is lower than the set first reference temperature, the opening of the intermediate pressure control valve is decreased and the opening of the downstream control valve is increased, and when the temperature of the fuel discharged from the primary heating part is higher than the first reference temperature, The opening degree of the intermediate pressure control valve may be increased and the opening degree of the downstream control valve may be decreased.

In the valve control step according to one aspect of the present invention, the temperature of the fuel is adjusted by adjusting the fuel control valve installed in the bypass pipe for supplying fuel to the upstream side of the secondary heating unit by bypassing the primary heating unit, When the temperature of the fuel discharged from the differential heating unit is lower than the preset second reference temperature, the opening of the fuel control valve is reduced, and when the fuel control valve is closed, the opening of the intermediate control valve is increased. When the temperature of the fuel discharged from the secondary heating unit is higher than the second reference temperature, the opening degree of the fuel control valve may be increased, and when the fuel control valve is fully opened, the opening degree of the intermediate control valve may be decreased. .

As described above, the combined power generation system according to one aspect of the present invention can supply sufficient heat to the fuel by supplying water from the high-pressure unit to the secondary heating unit and supplying water discharged from the secondary heating unit to the primary heating unit. In addition, it is possible to prevent the fuel from overheating by controlling the temperature of the feed water using the feed water of the middle pressure part.

1 is a configuration diagram showing a combined power generation system according to a first embodiment of the present invention.
2 is a configuration diagram showing a fuel preheater and an exhaust heat recovery boiler according to a first embodiment of the present invention.
3 is a configuration diagram showing a fuel preheater according to a first embodiment of the present invention.
4 is a flowchart illustrating a method of driving a combined power generation system according to a first embodiment of the present invention.
5 is a configuration diagram showing a fuel preheater according to a second embodiment of the present invention.
6 is a configuration diagram showing a fuel preheater according to a third embodiment of the present invention.
7 is a configuration diagram showing a fuel preheater according to a fourth embodiment of the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments will be exemplified and described in detail in the detailed description. However, it should be understood that this is not intended to limit the present invention to specific embodiments, and includes all transformations, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In the present invention, terms such as 'include' or 'having' are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. At this time, it should be noted that in the accompanying drawings, the same components are indicated by the same reference numerals as much as possible. In addition, detailed descriptions of well-known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, in the accompanying drawings, some components are exaggerated, omitted, or schematically illustrated.

Hereinafter, a gas turbine according to a first embodiment of the present invention will be described.

1 is a configuration diagram showing a combined power generation system according to a first embodiment of the present invention, FIG. 2 is a configuration diagram showing a fuel preheater and a heat recovery boiler according to a first embodiment of the present invention, and FIG. It is a configuration diagram showing the fuel preheater according to the first embodiment of the present invention.

Referring to FIGS. 1 to 3 , the combined power generation system 100 according to the first embodiment includes a plurality of turbines and generates electric power. The combined power generation system 100 includes a gas turbine 110, a generator 130, a heat recovery boiler 140, a steam turbine 120, a fuel preheater 150, a high pressure water supply pipe 153, a water delivery pipe 155, A water supply control pipe 154, a downstream control valve 161, and an intermediate control valve 162 may be included.

The gas turbine 110 according to this embodiment takes atmospheric air, compresses it to a high pressure, burns fuel in a constant pressure environment to release thermal energy, expands the high-temperature combustion gas, converts it into kinetic energy, and then converts the remaining energy into kinetic energy. The exhaust gas containing the can be released into the atmosphere.

The gas turbine 110 may include a compressor 112 , a combustor 115 , and a main turbine 113 . The compressor 112 of the gas turbine 110 may intake and compress air from the outside. The compressor 112 may supply compressed air compressed by the compressor blades to the combustor 115 and may also supply cooling air to a high-temperature region in the gas turbine 110 requiring cooling. At this time, since the sucked air undergoes an adiabatic compression process in the compressor 112, the pressure and temperature of the air passing through the compressor 112 increase.

The compressor 112 is designed as centrifugal compressors or axial compressors. A centrifugal compressor is applied in a small gas turbine, whereas a multi-stage axial compressor is applied in the same large gas turbine 110.

Meanwhile, the combustor 115 may mix compressed air supplied from the outlet of the compressor 112 with fuel and perform constant pressure combustion to produce high-energy combustion gas.

The high-temperature, high-pressure combustion gas produced by the combustor 115 is supplied to the main turbine 113 . In the main turbine 113, the thermal energy of the combustion gas is converted into mechanical energy by which the rotation shaft rotates by colliding and giving a reaction force to a plurality of blades arranged radially on the rotation shaft of the main turbine 113 while the combustion gas expands adiabatically. Part of the mechanical energy obtained from the main turbine 113 is supplied as energy required to compress air in the compressor 112, and the rest is used as effective energy such as generating electric power by driving the generator 130.

The combustion gas discharged from the main turbine 113 is cooled through the heat recovery boiler 140, purified, and discharged to the outside. The heat recovery boiler 140 not only cools the combustion gas, but also generates high-temperature and high-pressure steam by using the heat of the combustion gas, and transfers it to the steam turbine 120.

Steam generated in the heat recovery boiler 140 is transferred to the steam turbine 120 through the steam supply line 181, and the feed water cooled in the steam turbine 120 passes through the turbine feed water recovery line 182 to the heat recovery boiler. forwarded to (140).

The steam turbine 120 rotates blades using the steam generated by the heat recovery boiler 140 and transmits rotational energy to the generator 130. The steam turbine 120 supplies cooled steam to the heat recovery boiler 140 again.

In the first embodiment, the main turbine 113 and the steam turbine 120 are illustrated as being connected to one generator 130, but the present invention is not limited thereto, and the steam turbine 120 and the main turbine 113 ) can be arranged in parallel and connected to different generators.

In the turbine feedwater recovery line 182, a condenser 121 for condensing steam, a condensate water storage tank 122 for storing the condensed feedwater, and a condensate pump 123 for supplying the condensate stored in the condensate water storage tank 122 to the heat recovery boiler are provided. can be installed

Steam moving inside the heat recovery boiler 140 may have two or three levels of pressure, and accordingly, the supply water is pressurized to two or three or more pressure levels. In this embodiment, it is exemplified that the heat recovery boiler 140 has three levels of pressure.

The heat recovery boiler 140 may include a low pressure part G1 having a relatively low pressure, a medium pressure part G2 having a medium pressure, and a high pressure part G3 having a relatively high pressure. The high-pressure part (G3) is disposed adjacent to the inlet side through which combustion gas is introduced and heated by high-temperature combustion gas, and the low-pressure part (G1) is disposed adjacent to the outlet side through which combustion gas is discharged and heated by low-temperature combustion gas. It can be.

Inside the heat recovery boiler 140, a condensate preheater 141, a low pressure evaporator 142, a medium pressure economizer 143, a medium pressure evaporator 144, a high pressure economizer 145, and a high pressure evaporator 146 are installed. In addition, superheaters (not shown) may be additionally installed on the upstream sides of the evaporators. Combustion gas discharged from the heat recovery boiler 140 may be discharged through a stack.

The low pressure unit G1 includes a condensate preheater 141, a low pressure evaporator 142, and a low pressure drum 147. The condensate stored in the condensate storage tank 122 is transferred to the condensate preheater 141 by the condensate pump 123, and the condensate preheater 141 heats the condensate through heat exchange with combustion gas. The feed water heated in the condensate preheater 141 is transferred to the deaerator 175 to remove gas from the condensed water.

Feed water is supplied from the deaerator 175 to the low pressure drum 147, and the low pressure evaporator 142 is connected to the low pressure drum 147 to heat the feed water stored in the low pressure drum 147 to convert it into steam, and then to the low pressure drum ( After separation of steam in 147), it may be supplied to the superheater.

Meanwhile, the middle pressure unit G2 includes a middle pressure economizer 143, a middle pressure evaporator 144, and a middle pressure drum 148. Water supplied from the deaerator 175 is supplied to the intermediate pressure economizer 143 by the intermediate pressure pump 172, and the intermediate pressure economizer 143 heats the supplied water through heat exchange with combustion gas. The water heated in the intermediate pressure economizer 143 is supplied to the intermediate pressure drum 148, and the intermediate pressure evaporator 144 is connected to the intermediate pressure drum 148 to heat the water stored in the intermediate pressure drum 148 and convert it into steam. After the steam is separated from the intermediate pressure drum 148, it may be supplied to the superheater.

The high-pressure unit G3 includes a high-pressure economizer 145, a high-pressure evaporator 146, and a high-pressure drum 149. Water supplied from the deaerator 175 is supplied to the high-pressure economizer 145 by the high-pressure pump 173, and the high-pressure economizer 145 heats the water through heat exchange with combustion gas. The water heated in the high-pressure economizer 145 is supplied to the high-pressure drum 149, and the high-pressure evaporator 146 is connected to the high-pressure drum 149 to heat the water stored in the high-pressure drum 149 and convert it into steam. After the steam is separated from the high-pressure drum 149, it may be supplied to the superheater.

Steam stored in the low-pressure drum 147, the intermediate-pressure drum 148, and the high-pressure drum 149 may be supplied to the respective low-pressure, medium-pressure, and high-pressure steam turbines after being heated in the superheater.

The high-pressure water supply pipe 153 connects the high-pressure part G3 and the fuel preheater 150 to supply high-temperature, high-pressure water to the fuel preheater 150 . A high-pressure valve 176 may be installed on a downstream side of the high-pressure water supply pipe 153 to control a flow rate of water supplied to the high-pressure water supply pipe 153 . Meanwhile, the water supply control pipe 154 connects the intermediate pressure unit G2 and the fuel preheater 150 to supply medium pressure water to the fuel preheater 150 .

The fuel preheater 150 receives fuel from the fuel supply unit 117 through the fuel supply pipe 157, heats it, and supplies it to the combustor 115. Here, the fuel may be made of gas, but the present invention is not limited thereto.

The fuel preheater 150 includes a primary heating unit 151 that primarily heats fuel and a secondary heating unit 152 that secondarily heats the heated fuel. The primary heating unit 151 receives fuel from the fuel supply unit 117, heats the fuel through heat exchange with relatively low-temperature feed water, and then transfers it to the secondary heating unit 152, and the secondary heating unit 152 ) heats the fuel delivered from the primary heating unit 151 to a high temperature through heat exchange with high-pressure water supply.

The high-pressure water supply pipe 153 is connected to the secondary heating unit 152 to supply high-temperature water to the secondary heating unit 152 . The high-pressure water supply pipe 153 is connected between the high-pressure economizer 145 and the high-pressure drum 149 to supply water heated by the high-pressure economizer 145 to the secondary heating unit 152 . Here, the high-pressure water supply is made of liquid rather than steam, and the phase of the water supply in the fuel preheater 150 does not change and maintains a liquid state. When the feedwater phase is changed in the fuel preheater 150, vibration may occur due to a rapid change in pressure.

The water delivery pipe 155 transfers the water cooled by heat exchange with the fuel in the secondary heating unit 152 to the primary heating unit 151 . Meanwhile, a water supply control pipe 154 is connected to the water delivery pipe 155 to supply medium-pressure water to the water delivery pipe 155 .

The water supply control pipe 154 is connected to a downstream side of the intermediate pressure pump 172 to supply pressurized water from the intermediate pressure pump 172 to the water delivery pipe 155 . In addition, since the water supply control pipe 154 is connected between the intermediate pressure pump 172 and the intermediate pressure economizer 143, unheated water is supplied from the intermediate pressure unit G2 to supply water to the primary heating unit 151. The temperature can be easily controlled to prevent the fuel from overheating.

In addition, since the water supply control pipe 154 is connected to the downstream side of the intermediate pressure pump 172, it can operate independently without affecting the intermediate pressure economizer 143. In addition, since the water supply that is not heated in the middle pressure part G2 is supplied to the primary heating part 151, the temperature of the water supply is low and the possibility of occurrence of steam-induced vibration is reduced. In addition, since the pressurized water supply is supplied at a high pressure from the medium pressure pump 172, the water supply pressure is high and the possibility of fuel gas leaking into the water supply side is reduced.

If the pipe supplying water is connected to the downstream side of the intermediate pressure economizer 143, it is difficult to control the temperature of the water supplied to the primary heating unit 151, vibration occurs due to the high temperature of the water supply, and the pressure of the water supply increases. Low problems may arise.

Meanwhile, the capacities of the primary heating unit 151 and the secondary heating unit 152 may be the same, and accordingly, water may be supplied to the water delivery pipe through the water supply control pipe 154 only when necessary. The water discharged from the secondary heating unit 152 and the water supplied from the water supply control pipe 154 are mixed and supplied to the primary heating unit 151 .

In the connection part P1 where the water supply control pipe 154 and the water supply delivery pipe 155 are connected, the upstream side has a higher pressure than the water supply control pipe 154, and the downstream side has a lower pressure than the water supply control pipe 154 or controls the water supply. It may have a pressure similar to that of tube 154.

When the downstream pressure of the water supply pipe 155 in the connection part P1 is the same as the pressure of the water supply control pipe 154, the water supply cannot move from the water supply control pipe 154 to the water supply pipe 155, and the water supply pipe If the downstream pressure of 155 is higher than the pressure of the water supply control pipe 154 , the water supply passing through the water supply pipe 155 may flow into the water supply control pipe 154 . In this way, the water supply control pipe 154 is connected to the water supply delivery pipe 155 to adjust the temperature of the water supply and the pressure of the water supply.

On the other hand, the water supply recovery pipe 158 is connected to the primary heating unit 151, and the water recovery pipe 158 is connected to the downstream side of the condensate pump 123 to heat the fuel in the primary heating unit 151. The discharged feed water is delivered to the heat recovery boiler 140.

A first thermometer T1 for measuring the temperature of the fuel discharged from the primary heating unit 151 is installed in the fuel supply pipe 157 between the primary heating unit 151 and the secondary heating unit 152, and A second thermometer T2 for measuring the temperature of the fuel discharged from the secondary heating unit 152 is installed in the fuel supply pipe 157 on the downstream side of the secondary heating unit 152 .

In addition, a downstream control valve 161 for controlling the flow rate of the water supply discharged from the primary heating unit 151 is installed in the water supply recovery pipe 158 . The downstream control valve 161 controls the flow rate of the water supplied from the water supply control pipe 154 and the water supplied moving through the water supply delivery pipe 155 . When the opening of the downstream control valve 161 is decreased, surplus high-pressure water supplied from the secondary heating unit 152 may be supplied to the intermediate pressure economizer 143 through the water supply control pipe 154 .

An intermediate control valve 162 is installed in the feed water delivery pipe 155 , and the intermediate control valve 162 controls the flow rate of the high-pressure feed water flowing into the secondary heating unit 152 . The intermediate control valve 162 is located between the connection part P1 to which the water supply control pipe 154 and the water supply delivery pipe 155 are connected and the secondary heating part 152.

Accordingly, when the opening of the downstream control valve 161 decreases and the opening of the intermediate control valve 162 remains increased, the amount of feed water moving through the secondary heating unit 152 increases, and the primary heating The flow rate of feed water moving through the unit 151 may decrease. When the opening of the downstream control valve 161 decreases, if the high-pressure water supply cannot move through the water supply control pipe 154, the flow is accumulated and the flow rate of the water supply moving through the secondary heating unit 152 also decreases A problem arises.

On the other hand, when the opening degree of the downstream control valve 161 increases, the medium-pressure water supplied through the water supply control pipe 154 together with the high-pressure water discharged from the secondary heating unit 152 passes through the water delivery pipe 155. It can be supplied to the secondary heating unit.

In addition, when the opening of the intermediate control valve 162 decreases, the flow rate of the water supply discharged from the secondary heating unit 152 decreases, so the flow rate of the medium pressure water supply flowing from the water supply control pipe 154 to the water delivery pipe 155 this will increase When the opening of the intermediate control valve 162 increases, the flow rate of the feedwater discharged from the secondary heating unit 152 increases, so the flow rate of the medium-pressure feedwater flowing from the feedwater control pipe 154 to the feedwater delivery pipe 155 decreases. will do

As described above, according to the first embodiment, the water heated in the high-pressure economizer 145 is transferred to the secondary heating unit through the high-pressure water supply pipe 153 so that the fuel can be heated to a high temperature, and the water supply control pipe 154 ) is installed between the intermediate pressure pump 172 and the intermediate pressure economizer 143 to easily adjust the temperature of the feed water flowing into the primary heating unit 151.

Hereinafter, a method for driving the combined power generation system according to the first embodiment of the present invention will be described. 4 is a flowchart illustrating a method of driving a combined power generation system according to a first embodiment of the present invention.

Referring to FIGS. 3 and 4 , the driving method of the combined power generation system according to the present embodiment may include a fuel preheating step ( S101 ), a fuel temperature determination step ( S102 ), and a valve control step ( S103 ).

In the fuel preheating step (S101), the water discharged from the secondary heating unit 152 and the water supplied from the middle pressure unit G2 are mixed and supplied to the primary heating unit 151, and the water heated in the high pressure unit G3 is mixed. is supplied to the secondary heating unit 152.

In the fuel preheating step (S101), water is supplied to the secondary heating unit 152 through the high-pressure water supply pipe 153 connected between the high-pressure economizer 145 and the high-pressure drum 149 in the high-pressure unit G3. In addition, in the fuel preheating step (S101), the water discharged from the secondary heating unit 152 is supplied to the primary heating unit 151 through the water delivery pipe 155, and the intermediate pressure pump 172 is supplied from the intermediate pressure unit G2. ) And the water supply control pipe 154 connected between the intermediate pressure economizer 143 is connected to the water delivery pipe 155 to supply water to the water delivery pipe 155.

In the fuel temperature determination step (S102), the temperatures of the fuel discharged from the primary heating unit 151 and the fuel discharged from the secondary heating unit 152 are measured and compared with reference temperatures. In the fuel temperature determination step (S102), the temperature of the fuel is measured using the first thermometer T1 installed between the primary heating unit 151 and the secondary heating unit 152, and then compared with the first reference temperature. After measuring the temperature of the fuel using the second thermometer T2 installed on the downstream side of the differential heating unit 152, the temperature is compared with the second reference temperature. Here, the preset first reference temperature, which is a comparison target of the temperature measured by the first thermometer, is lower than the preset second reference temperature, which is a comparison target of the temperature measured by the second thermometer. The first reference temperature and the second reference temperature may be set in various ranges according to the capacity of the gas turbine, the type of fuel, and the like.

The valve control step (S103) is the movement of the water supply between the downstream control valve 161 controlling the flow rate of the water supply discharged from the primary heating unit 151 and the primary heating unit 151 and the secondary heating unit 152. The temperature of the fuel is adjusted by adjusting the intermediate control valve 162 that controls the temperature.

In the valve control step (S103), when the temperature of the fuel discharged from the primary heating unit 151 is lower than the first reference temperature, the opening degree of the downstream control valve 161 is increased and discharged from the primary heating unit 151. When the temperature of the fuel to be used is higher than the first reference temperature, the opening degree of the downstream control valve 161 is reduced.

In addition, the valve control step (S103) increases the opening of the intermediate control valve 162 when the temperature of the fuel discharged from the secondary heating unit 152 is lower than the second reference temperature, and the secondary heating unit 152 When the temperature of the fuel discharged from is higher than the second reference temperature, the opening degree of the intermediate control valve 162 is reduced.

As described above, according to the first embodiment, the fuel can be efficiently preheated while preventing the fuel from overheating by including the valve control step (S103).

Hereinafter, a combined power generation system according to a second embodiment of the present invention will be described. 5 is a configuration diagram showing a fuel preheater according to a second embodiment of the present invention.

Referring to FIG. 5, the combined power generation system according to the second embodiment has the same structure as the combined power generation system according to the first embodiment except for the bypass pipe 156. Redundant descriptions are omitted.

A bypass pipe 156 bypassing the primary heating unit 151 and the secondary heating unit 152 and supplying fuel to the downstream side of the secondary heating unit 152 is connected to the fuel supply pipe 157 . In addition, a fuel control valve 163 for controlling the flow rate of fuel moving through the bypass pipe 156 is installed in the bypass pipe 156 .

The fuel control valve 163 controls the flow rate of the fuel passing through the primary heating unit 151 and the secondary heating unit 152, thereby more easily controlling the heating temperature of the fuel.

Hereinafter, a method for driving a combined power generation system according to a second embodiment of the present invention will be described.

Since the driving method of the combined power generation system according to the second embodiment is the same as the driving method of the combined power generation system according to the second embodiment except for the valve control step, redundant description of the same components will be omitted.

In the valve control step, the downstream control valve 161 controls the amount of water supplied from the primary heating unit 151 and the movement of the water supply between the primary heating unit 151 and the secondary heating unit 152 is controlled. A fuel control valve installed in the bypass pipe 156 that supplies fuel to the downstream side of the secondary heating unit 152 without passing through the intermediate control valve 162, the primary heating unit 151, and the secondary heating unit 152. (163) to adjust the temperature of the fuel.

The valve control step increases the opening degree of the downstream control valve 161 when the temperature of the fuel discharged from the primary heating unit 151 is lower than the preset first reference temperature, and the discharged from the primary heating unit 151 When the temperature of the fuel is higher than the first reference temperature, the opening degree of the downstream control valve 161 is reduced.

When the opening degree of the downstream control valve 161 increases, the amount of feed water flowing into the primary heating unit 151 for heating increases, so the temperature of the fuel can be increased. In addition, when the opening of the downstream control valve 161 is reduced, the amount of feed water flowing into the primary heating unit 151 for heating is reduced, so the temperature of the fuel can be lowered.

In addition, the valve control step reduces the opening of the fuel control valve 163 when the temperature of the fuel discharged from the secondary heating unit 152 is lower than the preset second reference temperature, and the fuel control valve 163 is closed. If not, the opening degree of the intermediate control valve 162 is increased.

In addition, the valve control step increases the opening of the fuel control valve 163 when the temperature of the fuel discharged from the secondary heating unit 152 is higher than the second reference temperature, and increases the opening of the fuel control valve 163 when the fuel control valve 163 is fully opened. The opening of the control valve 162 is reduced.

When the opening of the fuel control valve 163 is reduced, the amount of bypassed fuel decreases, so the temperature of the fuel rises. As the flow rate increases, the temperature of the fuel may rise.

On the other hand, when the opening of the fuel control valve 163 is increased, the amount of bypassed fuel increases, so the temperature of the fuel decreases, and when the opening of the intermediate control valve 162 decreases, the secondary heating unit 152 The temperature of the fuel may decrease due to the decrease in the flow rate of the inflowing feedwater.

When the bypass pipe 156 and the fuel control valve 163 are installed as in the second embodiment, overheating of the fuel can be effectively prevented while minimizing the amount of feed water used for preheating the fuel.

Hereinafter, a combined power generation system according to a third embodiment of the present invention will be described. 6 is a configuration diagram showing a fuel preheater according to a third embodiment of the present invention.

Referring to FIG. 6, the combined power generation system according to the third embodiment has the same structure as the combined power generation system according to the first embodiment except for the intermediate pressure control valve 165. Redundant descriptions are omitted.

An intermediate pressure control valve 165 is installed in the water supply control pipe 154 to adjust the flow rate of the water supplied from the water supply control pipe 154 to the water delivery pipe 155 . The medium pressure control valve 165 not only prevents the reverse flow of the water supply but also controls the inflow amount of the low-temperature water supply supplied through the water supply control pipe 154 . Accordingly, the temperature of the water supplied to the primary heating unit 151 through the water supply control pipe 154 can be more easily adjusted.

On the other hand, a bypass pipe 156 for supplying fuel to the downstream side of the secondary heating unit 152 without passing through the primary heating unit 151 and the secondary heating unit 152 is connected to the fuel supply pipe 157. . In addition, a fuel control valve 163 for controlling the flow rate of fuel moving through the bypass pipe 156 is installed in the bypass pipe 156 .

Hereinafter, a method for driving a combined power generation system according to a third embodiment of the present invention will be described.

Since the driving method of the combined power generation system according to the third embodiment is the same as the driving method of the combined power generation system according to the third embodiment except for the valve control step, redundant description of the same components will be omitted.

In the valve control step, the temperature of the fuel is adjusted by adjusting the downstream control valve 161, the intermediate control valve 162, the fuel control valve 163, and the intermediate pressure control valve 165. In the valve control step, when the temperature of the fuel discharged from the primary heating unit 151 is lower than the preset first reference temperature, the opening degree of the intermediate pressure control valve 165 is reduced and the opening degree of the downstream control valve 161 is increased. increase Meanwhile, when the temperature of the fuel discharged from the primary heating unit 151 is higher than the first reference temperature, the opening degree of the intermediate pressure control valve 165 is increased and the opening degree of the downstream control valve 161 is decreased.

When the degree of opening of the intermediate pressure control valve 165 decreases, the flow rate of the intermediate pressure feed water having a relatively low temperature decreases, so the temperature of the feed water flowing into the primary heating unit increases, and when the degree of opening of the intermediate pressure control valve 165 increases Since the flow rate of the medium-pressure feed water having a relatively low temperature increases, the temperature of the feed water flowing into the primary heating unit may decrease.

In addition, the valve control step reduces the opening of the fuel control valve 163 when the temperature of the fuel discharged from the secondary heating unit 152 is lower than the preset second reference temperature, and the fuel control valve 163 is closed. If not, the opening degree of the intermediate control valve 162 is increased.

In addition, the valve control step increases the opening of the fuel control valve 163 when the temperature of the fuel discharged from the secondary heating unit 152 is higher than the second reference temperature, and increases the opening of the fuel control valve 163 when the fuel control valve 163 is fully opened. The opening of the control valve 162 is reduced.

When the medium pressure control valve 165 is installed as in the third embodiment, the heating temperature of the fuel can be efficiently controlled by controlling the flow rate of the medium pressure water supply flowing into the water supply pipe 155 through the water supply control pipe 154. can

Hereinafter, a combined power generation system according to a fourth embodiment of the present invention will be described. 7 is a configuration diagram showing a fuel preheater according to a fourth embodiment of the present invention.

Referring to FIG. 7, since the combined power generation system according to the fourth embodiment has the same structure as the combined power generation system according to the first embodiment except for the bypass pipe 166, the same configuration Redundant descriptions are omitted.

A bypass pipe 166 for supplying fuel to the upstream side of the secondary heating unit 152 without passing through the primary heating unit 151 is connected to the fuel supply pipe 157. In addition, a fuel control valve 167 for controlling the flow rate of fuel moving through the bypass pipe 166 is installed in the bypass pipe 166 .

One end of the bypass pipe 166 is connected to the upstream side of the primary heating unit, and the other end of the bypass tube 166 is connected to the fuel supply pipe between the primary heating unit 151 and the secondary heating unit 152. Connected. Accordingly, the bypass pipe 166 bypasses only the primary heating unit 151, and the fuel moving through the bypass tube 166 flows into the secondary heating unit 152.

Hereinafter, a method for driving a combined power generation system according to a fourth embodiment of the present invention will be described.

Since the driving method of the combined power generation system according to the fourth embodiment is the same as the driving method of the combined power generation system according to the fourth embodiment except for the valve control step, redundant description of the same components will be omitted.

In the valve control step, the downstream control valve 161 controls the amount of water supplied from the primary heating unit 151 and the movement of the water supply between the primary heating unit 151 and the secondary heating unit 152 is controlled. By adjusting the fuel control valve 167 installed in the bypass pipe 166 that supplies fuel to the upstream side of the secondary heating unit 152 without going through the intermediate control valve 162 and the primary heating unit 151, Adjust the temperature.

The valve control step increases the opening degree of the downstream control valve 161 when the temperature of the fuel discharged from the primary heating unit 151 is lower than the preset first reference temperature, and the discharged from the primary heating unit 151 When the temperature of the fuel is higher than the first reference temperature, the opening degree of the downstream control valve 161 is reduced.

In addition, the valve control step reduces the opening of the fuel control valve 167 when the temperature of the fuel discharged from the secondary heating unit 152 is lower than the preset second reference temperature, and the fuel control valve 167 is closed. If not, the opening degree of the intermediate control valve 162 is increased.

In addition, the valve control step increases the opening of the fuel control valve 167 when the temperature of the fuel discharged from the secondary heating unit 152 is higher than the second reference temperature, and increases the opening of the fuel control valve 167 when the fuel control valve 167 is fully opened. The opening of the control valve 162 is reduced.

When the bypass pipe 166 and the fuel control valve 167 are installed as in the fourth embodiment, overheating of the fuel can be effectively prevented while minimizing the quantity of feed water used for preheating the fuel.

Although one embodiment of the present invention has been described above, those skilled in the art can add, change, delete, or add components within the scope not departing from the spirit of the present invention described in the claims. The present invention can be variously modified and changed by the like, and this will also be said to be included within the scope of the present invention.

100: combined power generation system 110: gas turbine
112: compressor 115: combustor
113: main turbine 120: steam turbine
121: condenser 122: condensate storage tank
123: condensate pump 130: generator
140: heat recovery boiler 141: condensate preheater
142: low pressure evaporator 143: medium pressure economizer
144: medium pressure evaporator 145: high pressure economizer
146: high pressure evaporator 147: low pressure drum
148: medium pressure drum 149: high pressure drum
150: fuel preheater 151: primary heating unit
152: secondary heating unit 153: high-pressure water supply pipe
154: water control pipe 155: water delivery pipe
156, 166: bypass pipe 161: downstream control valve
162: intermediate control valve 163, 167: fuel control valve
165: medium pressure control valve 172: medium pressure pump
173: high-pressure pump 175: deaerator
176: high pressure valve 181: steam supply line
182: turbine feedwater recovery line

Claims (20)

A gas turbine generating rotational force by burning fuel;
a waste heat recovery boiler which heats feedwater using combustion gas discharged from the gas turbine and has a high pressure part, a medium pressure part, and a low pressure part having different pressure levels;
a fuel preheater which heats the fuel supplied to the gas turbine and has a primary heating unit and a secondary heating unit;
a high-pressure water supply pipe connected to the high-pressure unit and supplying high-pressure water to the secondary heating unit;
a water delivery pipe connecting the secondary heating unit and the primary heating unit to supply water discharged from the secondary heating unit to the primary heating unit;
a water supply control pipe connected to the middle pressure unit to supply medium pressure water to the water delivery pipe;
an intermediate control valve installed between the primary heating unit and the secondary heating unit to control the flow rate of the high-pressure feed water flowing into the secondary heating unit;
Including,
The intermediate pressure unit includes an intermediate pressure pump that pressurizes and moves the water supply and a medium pressure economizer that receives water from the medium pressure pump and heats the water supply,
The water supply control pipe is connected between the intermediate pressure pump and the intermediate pressure economizer, and is connected to a downstream side of the intermediate pressure pump to receive water supply from the intermediate pressure pump;
The combined power generation system in which the water supplied through the high-pressure water supply pipe is made of a liquid, and the phase of the water supply in the fuel preheater is unchanged. delete According to claim 1,
The intermediate control valve controls the flow rate of the medium-pressure feedwater flowing in from the feedwater control pipe using a change in the flow rate of the high-pressure feedwater. According to claim 1,
The high-pressure unit includes a high-pressure economizer for heating feed water, a high-pressure drum for storing the feed water heated by the high-pressure economizer, and a high-pressure evaporator for heating water in the high-pressure drum and converting it into steam,
The high-pressure water supply pipe is connected between the high-pressure economizer and the high-pressure drum to receive water heated by the high-pressure economizer. According to claim 1,
The intermediate control valve is a combined power generation system located between a connection portion to which the water supply control pipe and the water supply delivery pipe are connected and the secondary heating unit. According to claim 1,
A combined power generation system further comprising a feed water recovery pipe for transferring the feed water discharged from the primary heating unit to a heat recovery boiler and a downstream control valve installed in the feed water recovery pipe to control the flow rate of the feed water discharged from the primary heating unit. . According to claim 6,
The combined power generation system in which surplus high-pressure feedwater discharged from the secondary heating unit by the downstream control valve is supplied to the intermediate-pressure economizer through the feedwater control pipe. According to claim 1,
Combined power generation further comprising a bypass pipe connecting an upstream of the primary heating unit and a downstream of the secondary heating unit to bypass the primary heating unit and the secondary heating unit and move fuel to a downstream side of the secondary heating unit. system. According to claim 1,
The combined power generation system further comprises a bypass pipe connecting upstream of the primary heating unit and upstream of the secondary heating unit to bypass the primary heating unit and move fuel to the secondary heating unit. According to claim 8 or 9,
A combined power generation system in which a fuel control valve for controlling the flow rate of fuel moving through the bypass pipe is installed in the bypass pipe. According to claim 1,
The primary heating unit and the secondary heating unit have the same capacity. According to claim 1,
A combined power generation system in which an intermediate pressure control valve is installed in the water supply control pipe to adjust the flow rate of water supplied from the water supply control pipe to the water supply delivery pipe. A gas turbine, a steam turbine, a heat recovery boiler, and a fuel preheater having a primary heating unit and a secondary heating unit for preheating fuel, and the heat recovery boiler is a combined power generation system including a low pressure unit, an intermediate pressure unit, and a high pressure unit. In the driving method,
A fuel preheating step of supplying the water heated in the high-pressure part to the secondary heating part, mixing the water discharged from the secondary heating part with the water supplied from the medium-pressure part, and supplying the mixed water to the primary heating part;
A fuel temperature determination step of measuring the temperature of the fuel discharged from the primary heating unit and the temperature of the fuel discharged from the secondary heating unit and comparing them with reference temperatures; and
A valve that controls the temperature of fuel by adjusting a downstream control valve that controls the flow rate of feed water discharged from the primary heating unit and an intermediate control valve that controls the movement of feed water between the primary heating unit and the secondary heating unit. control step;
Including,
In the fuel preheating step, water supplied through the water supply control pipe connected between the intermediate pressure pump and the intermediate pressure economizer of the intermediate pressure unit is mixed with the water discharged from the secondary heating unit and supplied to the primary heating unit, and the water supply control tube Is connected to the downstream side of the medium pressure pump,
In the fuel preheating step, water is supplied to the fuel preheater through a high-pressure water supply pipe, and the water supplied through the high-pressure water pipe is made of a liquid. driving method. delete According to claim 13,
In the fuel preheating step, the high-pressure water supply pipe is connected between the high-pressure economizer and the high-pressure drum of the high-pressure unit. According to claim 13,
In the valve control step, when the temperature of the fuel discharged from the primary heating unit is lower than a preset first reference temperature, the opening degree of the downstream control valve is increased, and the temperature of the fuel discharged from the primary heating unit is lower than the first reference temperature. When the temperature is higher than the first reference temperature, the opening degree of the downstream control valve is reduced;
When the temperature of the fuel discharged from the secondary heating unit is lower than the preset second reference temperature, the opening degree of the intermediate control valve is increased, and the temperature of the fuel discharged from the secondary heating unit is higher than the second reference temperature. A method of driving a combined power generation system that reduces the opening degree of the intermediate control valve when high. According to claim 13,
The valve control step bypasses the primary heating unit and the secondary heating unit and adjusts the temperature of the fuel by adjusting a fuel control valve installed in a bypass pipe for supplying fuel to the downstream side of the secondary heating unit, A combined power generation system that reduces the opening of the fuel control valve when the temperature of the fuel discharged from the heating unit is lower than the preset second reference temperature, and increases the opening of the intermediate control valve when the fuel control valve is closed. driving method. According to claim 17,
The valve control step increases the opening of the fuel control valve when the temperature of the fuel discharged from the secondary heating unit is higher than the second reference temperature, and opens the intermediate control valve when the fuel control valve is fully opened. A driving method of a combined power generation system that reduces the degree. According to claim 13,
The valve control step controls the temperature of the fuel by adjusting the intermediate pressure control valve that controls the flow rate of the feed water supplied from the intermediate pressure unit,
When the temperature of the fuel discharged from the primary heating unit is lower than the preset first reference temperature, the opening degree of the intermediate pressure control valve is reduced and the opening degree of the downstream control valve is increased, and the fuel is discharged from the primary heating unit. A method of driving a combined power generation system in which the opening of the middle pressure control valve is increased and the opening of the downstream control valve is decreased when the temperature of the fuel to be used is higher than the first reference temperature. According to claim 13,
In the valve control step, the temperature of the fuel is controlled by adjusting a fuel control valve installed in a bypass pipe for supplying fuel to the upstream side of the secondary heating unit by bypassing the primary heating unit, but the fuel discharged from the secondary heating unit is controlled. When the temperature of is lower than the preset second reference temperature, the opening of the fuel control valve is reduced, and when the fuel control valve is closed, the opening of the intermediate control valve is increased, and discharged from the secondary heating unit A method of driving a combined power generation system in which the opening of the fuel control valve is increased when the temperature of the fuel is higher than the second reference temperature, and the opening of the intermediate control valve is decreased when the fuel control valve is fully opened.

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