KR101926268B1 - Waste heat recycling system and method - Google Patents

Abstract

The present invention relates to a waste heat recycling system using heat of a working fluid and a method. According to an embodiment of the present invention, the waste heat recycling system may comprise a recycling line using heat of a working fluid to be supplied to a boiler as combustion air or heating the combustion air supplied to the boiler.

Description

TECHNICAL FIELD The present invention relates to a waste heat recovery system and method,

The present invention relates to a waste heat recovery system and method, and more particularly, to a waste heat recovery system and method using heat of a working fluid.

Generally, the power generation boiler superheats the steam and then transfers it to the turbine to convert the energy held by the steam into an axial force. At this time, the steam maintains a high temperature and high pressure state. The combustion exhaust gas after burning the steam in the boiler passes through the exhaust gas duct and eventually is discharged to the atmosphere through the chimney. Since the combustion exhaust gas at the boiler outlet is in a high temperature state, it has thermal energy, and the heat utilization efficiency of the boiler decreases as the amount of such thermal energy increases.

As a method for increasing the heat utilization efficiency of the boiler, an air preheater for preheating combustion air supplied to the burner by using combustion exhaust gas heat is installed in the exhaust gas duct. By doing so, it is possible to lower the temperature of the combustion exhaust gas at a high temperature, thereby increasing the heat utilization efficiency of the boiler. However, even when such an energy saving means is applied, the temperature of the combustion exhaust gas discharged through the exhaust gas duct reaches a high temperature, so that about 10% or more of the thermal energy supplied to the boiler is lost to the atmosphere through the exhaust gas.

The condenser is also a device that produces electricity from the turbine and emits heat that is no longer available to the cooling water or the atmosphere. About 50% of the fuel energy is lost to the atmosphere through the condenser.

Korean Patent Laid-Open No. 10-2010-0027281 (name: waste heat recovery apparatus for steam boiler)

One aspect of the present invention provides a waste heat recovery system and method that can utilize thermal energy that is discharged to the atmosphere through a condenser for boiler air preheating, thereby increasing boiler efficiency and further improving power generation efficiency and using coal fuel efficiently .

A waste heat recovery system according to an embodiment of the present invention includes a working fluid circulation line and a recovery line. The working fluid circulating line has a first conveying line, a second conveying line, a third conveying line, a fourth conveying line, a fifth conveying line, and a sixth conveying line. The first transfer line transfers the working fluid heated by the boiler to operate the turbine of the generator. In the second transfer line, the working fluid discharged through the turbine is heat-exchanged in the recuperator. In the third transfer line, the working fluid heat exchanged through the heat exchanger is condensed in an air cooled condenser. The fourth transfer line is compressed by the main pump with the working fluid condensed through the air-cooled condenser. In the fifth transfer line, the working fluid compressed by the main pump is heat-exchanged in the recuperator. In the sixth transfer line, the working fluid heat exchanged through the heat exchanger is reheated in the boiler. The recovery line recovers the waste heat generated in the working fluid circulation line to the combustion air of the boiler.

The recovery line according to an embodiment of the present invention may include a waste heat recovery line in which heated air passing through the air-cooled condenser is supplied to the boiler as combustion air.

The waste heat recovery line according to an embodiment of the present invention includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler, a flow rate control damper for adjusting the flow rate of air delivered through the waste heat recovery line, And a control unit in which the flow rate control damper is controlled in accordance with the oxygen concentration included in the exhaust gas measured through the control unit.

The waste heat recovery line according to an embodiment of the present invention includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler, a flow rate adjusting fan for controlling the flow rate of the air delivered through the waste heat recovery line, And the control unit may control the rotational speed of the flow rate adjusting fan according to the concentration of oxygen contained in the exhaust gas measured through the control unit.

The recovery line according to an embodiment of the present invention may include a first branch line branched at the second transfer line and connected to the fourth transfer line via the heat dissipation unit. The first branch line includes a temperature sensor for measuring the temperature of the air passing through the heat dissipating unit to heat the combustion air supplied to the boiler, a flow control valve for controlling the flow rate of the working fluid delivered through the first branch line, And the flow rate control valve is controlled according to the temperature of the air to be measured.

The recovery line according to an embodiment of the present invention may include a second branch line that branches at the third transfer line and is connected to the fourth transfer line via the heat dissipation unit. The second branch line includes a temperature sensor for measuring the temperature of the air passing through the heat dissipating unit to heat the combustion air supplied to the boiler, a flow control valve for controlling the flow rate of the working fluid conveyed through the second branch line, And the flow rate control valve is controlled according to the temperature of the air to be measured.

The recovery line according to an embodiment of the present invention may include a third branch line branched at the third transfer line and reconnected to the third transfer line via the heat dissipation unit. The third branch line includes a temperature sensor for measuring the temperature of the air passing through the heat dissipating unit to heat the combustion air supplied to the boiler, a flow control valve and a temperature sensor for controlling the flow rate of the working fluid delivered through the third branch line And the flow rate control valve is controlled according to the temperature of the air to be measured.

The recovery line according to an embodiment of the present invention may include a fourth branch line branched at the sixth transfer line and connected to the fifth transfer line via the heat dissipation unit. The fourth branch line includes a temperature sensor for measuring the temperature of the air passing through the heat dissipating unit to heat the combustion air supplied to the boiler, a flow rate adjusting pump for controlling the flow rate of the working fluid fed through the fourth branch line, And the control unit controls the power of the flow rate adjusting pump according to the temperature of the air to be measured.

A waste heat recovery system according to an embodiment of the present invention includes a working fluid circulation line and a recovery line. The working fluid circulation line has a first conveying line, a second conveying line, a third conveying line, a fourth conveying line, a fifth conveying line, a sixth conveying line, a seventh conveying line and an eighth conveying line. The first transfer line transfers the working fluid heated by the boiler to operate the turbine of the generator. The second transfer line is heat exchanged with the working fluid discharged through the turbine at the first recuperator. The third transfer line is heat-exchanged in the second heat exchanger with the working fluid heat exchanged through the first recuperator. The fourth transfer line is such that the working fluid heat exchanged through the second condenser is condensed in the air-cooled condenser. The fifth transfer line is branched at the fourth transfer line and connected to the first sucker, and has a pump. The sixth transfer line is compressed by the main pump with the working fluid condensed through the air-cooled condenser. The seventh transfer line is connected to the fifth transfer line after the working fluid compressed by the main pump is heat exchanged in the second recuperator. The eighth conveyance line reheats the working fluid heat exchanged through the first condenser in the boiler. The recovery line recovers the waste heat generated in the working fluid circulation line to the combustion air of the boiler.

The recovery line according to an embodiment of the present invention may include a waste heat recovery line in which heated air passing through the air-cooled condenser is supplied to the boiler as combustion air.

The waste heat recovery line according to an embodiment of the present invention includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler, a flow rate control damper for adjusting the flow rate of air delivered through the waste heat recovery line, And a control unit in which the flow rate control damper is controlled in accordance with the oxygen concentration included in the exhaust gas measured through the control unit.

The waste heat recovery line according to an embodiment of the present invention includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler, a flow rate adjusting fan for controlling the flow rate of the air delivered through the waste heat recovery line, And the control unit may control the rotational speed of the flow rate adjusting fan according to the concentration of oxygen contained in the exhaust gas measured through the control unit.

The recovery line according to an embodiment of the present invention may include a first branch line branched at the third transfer line and connected to the sixth transfer line via the heat dissipation unit. The first branch line includes a temperature sensor for measuring the temperature of the air passing through the heat dissipating unit to heat the combustion air supplied to the boiler, a flow control valve for controlling the flow rate of the working fluid delivered through the first branch line, And the flow rate control valve is controlled according to the temperature of the air to be measured.

The recovery line according to an embodiment of the present invention may include a second branch line that branches at the third transfer line and is connected to the fourth transfer line via the heat dissipation unit. The second branch line includes a temperature sensor for measuring the temperature of the air passing through the heat dissipating unit to heat the combustion air supplied to the boiler, a flow control valve for controlling the flow rate of the working fluid conveyed through the second branch line, And the flow rate control valve is controlled according to the temperature of the air to be measured.

The recovery line according to an embodiment of the present invention may include a third branch line branched at the fifth transfer line and connected to the seventh transfer line via the heat dissipation unit. The third branch line includes a temperature sensor for measuring the temperature of the air passing through the heat dissipating unit to heat the combustion air supplied to the boiler, a flow rate adjusting pump and a temperature sensor for adjusting the flow rate of the working fluid delivered through the third branch line And the control unit controls the power of the flow rate adjusting pump according to the temperature of the air to be measured.

The waste heat recovery method according to an embodiment of the present invention includes a working fluid circulation step and a recovery step. The working fluid circulation step includes a power generation step, a first heat exchange step, a condensation step, a compression step, a second heat exchange step and a reheating step. In the power generation step, the working fluid heated by the boiler is conveyed through the first conveyance line to operate the turbine of the generator. In the first heat exchange step, the working fluid discharged through the turbine is transferred through the second transfer line and is subjected to the primary heat exchange in the recuperator. In the condensing step, the working fluid that has undergone the primary heat exchange through the heat exchanger is transferred through the third transfer line and condensed in the air-cooled condenser. In the compressing step, the working fluid condensed through the air-cooled condenser is conveyed through the fourth conveyance line and compressed by the main pump. In the second heat exchange step, the working fluid compressed by the main pump is transferred through the fifth transfer line and is subjected to secondary heat exchange in the recuperator. In the reheating step, the working fluid that has undergone the second heat exchange through the heat exchanger is transferred through the sixth transfer line and reheated in the boiler. In the recovery step, the air heated by the waste heat generated in the working fluid circulation step is recovered into the combustion air of the boiler.

The recovering step according to an embodiment of the present invention may include a waste heat recovery step in which heated air passing through the air-cooled condenser is supplied to the boiler as combustion air.

The recovering step according to an embodiment of the present invention may include a first branching step in which the working fluid is branched in the second conveying line and joined to the fourth conveying line via the heat dissipating unit and the combustion air supplied to the boiler by the air passing through the heat- And a heated combustion air heating step.

The recovering step according to an embodiment of the present invention includes a second branching step in which the working fluid is branched in the third conveying line and joined to the fourth conveying line via the heat dissipating unit and the combustion air supplied to the boiler by the air passing through the heat- And a heated combustion air heating step.

The recovery step according to an embodiment of the present invention may include a third branching step in which the working fluid is branched in the third transfer line and re-merged into the third transfer line via the heat dissipating unit, and the combustion air supplied to the boiler by the air passing through the heat- And a combustion air heating step in which the combustion air is heated.

The recovering step according to an embodiment of the present invention may include a fourth branching step in which the working fluid is branched in the sixth conveying line and joined to the fifth conveying line via the heat dissipating unit and the combustion air supplied to the boiler by the air passing through the heat- And a heated combustion air heating step.

The waste heat recovery method according to an embodiment of the present invention includes a working fluid circulation step and a recovery step. The working fluid circulation step includes a power generation step, a first heat exchange step, a second heat exchange step, a condensation step, a third heat exchange step, a compression step, a merging step and a reheating step. In the power generation step, the working fluid heated by the boiler is conveyed through the first conveyance line to operate the turbine of the generator. In the first heat exchange step, the working fluid discharged through the turbine is transferred through the second transfer line and subjected to the primary heat exchange in the first recuperator. In the second heat exchange step, the working fluid that has undergone the primary heat exchange through the first recuperator is conveyed through the third conveyance line and is subjected to the secondary heat exchange in the second recuperator. In the condensing step, the working fluid that has undergone the second heat exchange through the second condenser is conveyed through the fourth conveyance line and condensed in the air-cooled condenser. The third heat exchanging step is branched at the fourth conveying line and is subjected to tertiary heat exchange in the first recuperator while being pressurized through the fifth conveying line equipped with the pump. In the compressing step, the working fluid condensed through the air-cooled condenser is conveyed through the sixth conveying line and compressed by the main pump. The joining step is such that the working fluid compressed by the main pump is transferred through the seventh transfer line and tertiary heat exchanged in the second recuperator, and then joined to the fifth transfer line. The reheating step is such that the working fluid heat exchanged through the first recuperator is transferred through the eighth transfer line and reheated in the boiler. In the recovery step, the air heated by the waste heat generated in the working fluid circulation step is recovered into the combustion air of the boiler.

The recovering step according to an embodiment of the present invention may include a waste heat recovery step in which heated air passing through the air-cooled condenser is supplied to the boiler as combustion air.

According to an embodiment of the present invention, the recovering step includes a first branching step in which the working fluid is branched in the third conveying line and joined to the sixth conveying line via the heat dissipating unit, and the combustion air supplied to the boiler by the air passing through the heat- And a heated combustion air heating step.

The recovering step according to an embodiment of the present invention includes a second branching step in which the working fluid is branched in the third conveying line and joined to the fourth conveying line via the heat dissipating unit and the combustion air supplied to the boiler by the air passing through the heat- And a heated combustion air heating step.

The recovery step according to an embodiment of the present invention may include a third branching step in which the working fluid is branched in the fifth transfer line and joined to the seventh transfer line via the heat dissipating unit and the combustion air supplied to the boiler by the air passing through the heat- And a heated combustion air heating step.

According to the embodiments of the present invention, the heat of the working fluid is supplied to the combustion air of the boiler or the combustion air supplied to the boiler is heated, so that the thermal efficiency of the boiler is improved and the fuel can be saved.

1 is a diagram illustrating a waste heat recovery system and method according to an embodiment of the present invention.
2 is a view showing another embodiment of the waste heat recovery system of FIG.
3 is a view showing another embodiment of the waste heat recovery system of FIG.
4 is a diagram illustrating a waste heat recovery system and method according to another embodiment of the present invention.
5 is a view showing another embodiment of the waste heat recovery system and method of FIG.
6 is a view showing another embodiment of the waste heat recovery system and method of FIG.
7 is a view showing another embodiment of the waste heat recovery system and method of FIG.
FIG. 8 is a diagram illustrating a waste heat recovery system and method using a recompression Braaton cycle according to an embodiment of the present invention.
9 is a diagram showing another embodiment of the waste heat recovery system to which the recompression break-down cycle of FIG. 8 is applied.
10 is a view showing another embodiment of a waste heat recovery system to which the recompression break-through cycle of FIG. 8 is applied.
11 is a diagram illustrating a waste heat recovery system and method using a recompression Braaton cycle according to another embodiment of the present invention.
12 is a diagram showing another embodiment of a waste heat recovery system and method to which the recompression Braaton cycle of FIG. 11 is applied.
FIG. 13 is a diagram showing another embodiment of a waste heat recovery system and method to which the recompression Braaton cycle of FIG. 11 is applied.

The present invention is capable of various modifications and various embodiments and is intended to illustrate and describe the specific embodiments in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present invention, terms such as "comprises" or "having" are used to designate the presence of stated features, integers, steps, operations, elements, components, or combinations thereof, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some of the components in the drawings are exaggerated, omitted, or schematically illustrated.

The waste heat recovery system and method according to the present invention can be applied to various types of power generation systems such as gas turbine generation, SCO2 supercritical power generation system, and steam generation.

1 is a diagram illustrating a waste heat recovery system and method according to an embodiment of the present invention. Referring to FIG. 1, a waste heat recovery method according to an embodiment of the present invention includes a working fluid circulation step and a recovery step.

The working fluid circulation step includes a power generation step, a first heat exchange step, a condensation step, a compression step, a second heat exchange step and a reheating step.

In the power generation step, the working fluid heated by the boiler B is conveyed through the first conveyance line 1110 to operate the turbine of the generator G. [ In the first heat exchange step, the working fluid discharged through the turbine is transferred through the second transfer line 1120 and subjected to the primary heat exchange at the heat exchanger R. [ The condensing step is such that the working fluid that has undergone the primary heat exchange through the heat exchanger (R) is transferred through the third transfer line (1130) and condensed in the air-cooled condenser (A). In the compressing step, the working fluid condensed through the air-cooled condenser A is conveyed through the fourth conveyance line 1140 and compressed by the main pump P. In the second heat exchange step, the working fluid compressed by the main pump (P) is transferred through the fifth transfer line (1150) and subjected to second heat exchange in the heat exchanger (R). The reheating step is such that the working fluid secondary heat exchanged through the heat exchanger (R) is transferred through the sixth transfer line (1160) and reheated in the boiler (B).

In the recovery step, the air heated by the waste heat generated in the working fluid circulation step is recovered into the combustion air of the boiler (B). The recovery step includes a waste heat recovery step. In the waste heat recovery step, the heated air passing through the air-cooled condenser (A) is supplied to the boiler (B) as combustion air.

Referring to FIG. 1, a waste heat recovery system 1000 according to an embodiment of the present invention includes a working fluid circulation line 1100 and a recovery line 1200.

The working fluid circulating line 1100 includes a first conveying line 1110, a second conveying line 1120, a third conveying line 1130, a fourth conveying line 1140, a fifth conveying line 1150, And a transfer line 1160.

(B) through which the combustion air sucked from the outside is forcibly supplied by the forced draft fan (FD FAN) together with the fuel to generate the combustion heat, and the working fluid raised at a temperature of about 600 ° C. and a pressure of about 240 bar And is conveyed through the first conveyance line 1100. The turbine of the generator (G) is operated by the working fluid thus conveyed. The exhaust gas discharged from the boiler (B) is discharged to the outside through the chimney. At this time, the working fluid is any one of water, carbon dioxide (CO 2), and supercritical carbon dioxide (SCO 2), but is not limited thereto.

The working fluid discharged through the turbine is transferred to the recuperator R through the second transfer line 1120. The working fluid discharged from the turbine is about 450 ° C, about 80 bar, and the temperature of the working fluid drops to about 50 ° C due to heat exchange through the recuperator (R).

The working fluid heat exchanged in the heat exchanger (R) is transferred to the air cooled condenser (A) through the third transfer line (1130). The temperature of the working fluid passing through the air-cooled condenser (A) by the air cooler fan located at the front end of the air-cooled condenser (A) is cooled to about 20 캜.

The working fluid condensed through the air-cooled condenser (A) is transferred to the main pump (P) through the fourth transfer line (1140). The working fluid thus conveyed is compressed by the main pump P, and the pressure rises.

The working fluid compressed by the main pump P is transferred to the recuperator R through the fifth transfer line 1150. [ The temperature of the working fluid rises as heat is exchanged through the heat exchanger (R).

The working fluid, which is heat-exchanged through the double heat exchanger (R), is transferred to the boiler (B) through the sixth transfer line (1160). The working fluid reheated in the boiler B rises to a temperature of about 600 ° C and a pressure of about 240 bar.

In the recovery line 1200, the air heated by the waste heat generated in the working fluid circulation line 1100 is recovered into the combustion air of the boiler B. The recovery line 1200 has a waste heat recovery line 1210 in which heated air having passed through the air-cooled condenser A is supplied to the boiler B as combustion air.

When the air cooler fan located at the front end of the air-cooled condenser A rotates toward the air-cooled condenser A, the air on the front-end side of the air-cooled condenser A is heated while passing through the air-cooled condenser A, The air having been raised in temperature is recovered and supplied to the boiler B through the waste heat recovery line 1210 as combustion air. When the air raised by about 10 to 20 ° C through the waste heat recovery line 1210 is used as the combustion air of the boiler B, the fuel supplied to the boiler B can be saved, B) increases. In addition, the system can be simplified by integrating the separately operated boiler (B) pressurized blower and the air-cooled condenser (A) air cooler fan into one.

2 is a diagram illustrating a waste heat recovery system according to another embodiment of the present invention. 2, the waste heat recovery line 1210 includes an oxygen sensor 1211, a flow rate control damper 1212, and a controller 1213. The oxygen sensor 1211 measures the concentration of oxygen contained in the exhaust gas discharged from the boiler (B). The flow control damper 1212 regulates the flow rate of the air delivered through the waste heat recovery line 1210. The control unit 1213 controls the flow rate control damper 1212 in accordance with the oxygen concentration contained in the exhaust gas measured by the oxygen sensor 1211.

If the concentration of oxygen contained in the exhaust gas discharged from the boiler B is measured to be higher or lower than the designed value, the efficiency is lowered due to the incomplete combustion of the boiler B. Therefore, the flow rate control damper 1212 is used to control the waste heat recovery line (1210). ≪ / RTI >

3 is a diagram illustrating a waste heat recovery system according to another embodiment of the present invention. 3, the waste heat recovery line 1210 includes an oxygen sensor 1211, a flow rate regulating fan 1214, and a controller 1215. The oxygen sensor 1211 measures the concentration of oxygen contained in the exhaust gas discharged from the boiler (B). The flow regulation fan 1214 regulates the flow rate of the air delivered through the waste heat recovery line 1210. The controller 1215 controls the rotational speed of the flow rate regulating fan 1214 according to the oxygen concentration contained in the exhaust gas measured by the oxygen sensor 1211.

When the concentration of oxygen contained in the exhaust gas discharged from the boiler B is measured to be higher or lower than the designed value, the efficiency is lowered due to the incomplete combustion of the boiler B, so that the rotational speed of the flow regulating fan 1214 is adjusted And controls the flow rate of air delivered through the waste heat recovery line 1210.

4 is a diagram illustrating a waste heat recovery system and method according to another embodiment of the present invention. Referring to FIG. 4, in the waste heat recovery method according to another embodiment of the present invention, the recovery step includes a first branching step and a combustion air heating step.

In the first branching step, the working fluid is branched in the second transfer line 1120 and joined to the fourth transfer line 1140 through the heat dissipating portion H. [ In the combustion air heating step, the combustion air supplied to the boiler (B) is heated by the air passing through the heat dissipating portion (H).

Referring to FIG. 4, in the waste heat recovery system 1000 according to another embodiment of the present invention, the recovery line 1200 is branched by the working fluid of about 450 ° C temperature transferred through the second transfer line 1120, And a first branch line 1220 through which the working fluid that has fallen to a temperature of about 20 ° C joins the fourth transfer line 1140.

The branch lines to be described later are not used to recover the air downstream of the air-cooled condenser A and supply the air to the combustion air of the boiler B, but a separate heat-radiating portion H may be provided in front of the boiler B in which the combustion air is sucked A part of the working fluid circulating through the working fluid circulating line 1100 is branched and passes through the heat dissipating unit H and is then reconnected to the working fluid circulating line 1100.

The first branch line 1220 includes a temperature sensor 1221, a flow control valve 1222, and a control unit 1223. The temperature sensor 1221 measures the temperature of the air that has passed through the heat dissipating unit H to heat the combustion air supplied to the boiler B. [ The flow regulating valve 1222 regulates the flow rate of the working fluid delivered through the first branch line 1220. The control unit 1223 controls the flow rate regulating valve 1222 in accordance with the temperature of the air measured by the temperature sensor 1221.

When the temperature of the combustion air supplied to the boiler B is higher than the designed value, the heat of combustion of the boiler B excessively rises and the boiler B may be overheated. If the temperature is measured to be low, The flow rate control valve 1222 is used to control the flow rate of the working fluid delivered through the first branch line 1220. [

5 is a diagram illustrating a waste heat recovery system and method according to another embodiment of the present invention. Referring to FIG. 5, in the waste heat recovery method according to another embodiment of the present invention, the recovery step includes a second branching step and a combustion air heating step.

In the second branching step, the working fluid is branched in the third feeding line 1130 and joined to the fourth feeding line 1140 via the heat dissipating portion H. [ In the combustion air heating step, the combustion air supplied to the boiler (B) is heated by the air passing through the heat dissipating portion (H).

5, in the waste heat recovery system 1000 according to another embodiment of the present invention, the recovery line 1200 is branched from the waste heat recovery system 1000 in such a manner that the working fluid at a temperature of about 50 ° C, which is transferred through the third transfer line 1130, And a second branch line 1230 through which the working fluid, which has fallen to a temperature of about 30 占 폚, joins the fourth transfer line 1140.

The second branch line 1230 includes a temperature sensor 1231, a flow control valve 1232, and a controller 1233. The temperature sensor 1231 measures the temperature of the air that has passed through the heat dissipating unit H to heat the combustion air supplied to the boiler B. The flow regulating valve 1232 regulates the flow rate of the working fluid delivered through the second branch line 1230. The control unit 1233 controls the flow rate control valve 1232 in accordance with the temperature of the air measured by the temperature sensor 1231.

When the temperature of the combustion air supplied to the boiler B is higher than the designed value, the heat of combustion of the boiler B excessively rises and the boiler B may be overheated. If the temperature is measured to be low, The flow rate control valve 1232 is used to control the flow rate of the working fluid being conveyed through the second branch line 1230.

6 is a diagram illustrating a waste heat recovery system and method according to another embodiment of the present invention. Referring to FIG. 6, in the waste heat recovery method according to another embodiment of the present invention, the recovery step includes a third branching step and a combustion air heating step.

In the third branching step, the working fluid is branched in the third feeding line 1130 and re-joined to the third feeding line 1130 via the heat dissipating portion H. In the combustion air heating step, the combustion air supplied to the boiler (B) is heated by the air passing through the heat dissipating portion (H).

Referring to FIG. 6, in the waste heat recovery system 1000 according to another embodiment of the present invention, the recovery line 1200 is branched by the operation fluid of about 50 ° C temperature transferred through the third transfer line 1130, (H), and then rejoins the third transfer line (1130). This structure is for further cooling in the air-cooled condenser (A) when the temperature of the working fluid passing through the heat dissipating part (H) is not sufficiently lowered.

The third branch line 1240 includes a temperature sensor 1241, a flow control valve 1242, and a controller 1243. The temperature sensor 1241 measures the temperature of the air that has passed through the heat dissipating unit H to heat the combustion air supplied to the boiler B. [ The flow control valve 1242 regulates the flow rate of the working fluid delivered through the third branch line 1240. The control unit 1243 controls the flow rate control valve 1242 in accordance with the temperature of the air measured by the temperature sensor 1241.

When the temperature of the combustion air supplied to the boiler B is higher than the designed value, the heat of combustion of the boiler B excessively rises and the boiler B may be overheated. If the temperature is measured to be low, The flow rate control valve 1242 is used to control the flow rate of the working fluid being fed through the third branch line 1240.

7 is a diagram illustrating a waste heat recovery system and method according to another embodiment of the present invention. Referring to FIG. 7, in the waste heat recovery method according to another embodiment of the present invention, the recovery step includes a fourth branching step and a combustion air heating step.

In the fourth branching step, the working fluid is branched in the sixth feeding line 1160 and joined to the fifth feeding line 1150 via the heat radiating portion H. [ In the combustion air heating step, the combustion air supplied to the boiler (B) is heated by the air passing through the heat dissipating portion (H).

Referring to FIG. 7, in the waste heat recovery system 1000 according to another embodiment of the present invention, the recovery line 1200 is branched from the high-temperature and high-pressure working fluid transferred through the sixth transfer line 1160, , And then a fourth branch line 1250 in which a working fluid at a temperature of about 30 ° C and a pressure of about 235 bar merges into the fifth transfer line 1150. Here, instead of the air-cooled condenser A applied to the working fluid circulation line 1100, a water-cooled condenser may be applied.

The fourth branch line 1250 includes a temperature sensor 1251, a flow rate control pump 1252, and a control unit 1253. The temperature sensor 1251 measures the temperature of the air that has passed through the heat dissipating unit H to heat the combustion air supplied to the boiler B. [ The flow regulation pump 1252 regulates the flow rate of the working fluid delivered through the fourth branch line 1250. The control unit 1253 controls the power of the flow rate regulating pump 1252 according to the temperature of the air measured by the temperature sensor 1251.

When the temperature of the combustion air supplied to the boiler B is higher than the designed value, the heat of combustion of the boiler B excessively rises and the boiler B may be overheated. If the temperature is measured to be low, And controls the flow rate of the working fluid delivered through the fourth branch line 1250 by regulating the power of the flow regulating pump 1252. [

FIG. 8 is a diagram illustrating a waste heat recovery system and method using a recompression Braaton cycle according to an embodiment of the present invention. Referring to FIG. 8, a waste heat recovery method using a recompression Braaton cycle according to an embodiment of the present invention includes a working fluid circulation step and a recovery step.

The working fluid circulation step includes a power generation step, a first heat exchange step, a second heat exchange step, a condensation step, a third heat exchange step, a compression step, a merging step and a reheating step.

In the power generation step, the working fluid heated by the boiler is conveyed through the first conveyance line 2110 to operate the turbine of the generator G. [ In the first heat exchange step, the working fluid discharged through the turbine is transferred through the second transfer line 2120 and subjected to the primary heat exchange in the first recuperator R1. In the second heat exchange step, the working fluid subjected to the first heat exchange through the first heat exchanger (R1) is transferred through the third transfer line (2130) and the second heat exchanger is performed in the second heat exchanger (R2). In the condensing step, the working fluid secondary-heat-exchanged through the second condenser R2 is transferred through the fourth transfer line 2140 and condensed in the air-cooled condenser A. The third heat exchanging step is branched from the fourth conveying line 2140 and is subjected to tertiary heat exchange in the first heat exchanger R1 while being pressurized through the fifth conveying line 2150 provided with the pump p. In the compressing step, the working fluid condensed through the air-cooled condenser A is conveyed through the sixth conveyance line 2160 and compressed by the main pump P. The joining step is such that the working fluid compressed by the main pump P is conveyed through the seventh conveyance line 2170 and tertiary heat exchanged in the second recuperator R2 and then joined to the fifth conveyance line 2150 . The reheating step is such that the working fluid heat exchanged through the first recuperator R1 is transferred through the eighth transfer line 2180 and reheated in the boiler B. [

In the recovery step, the air heated by the waste heat generated in the working fluid circulation step is recovered into the combustion air of the boiler (B). The recovery step includes a waste heat recovery step. In the waste heat recovery step, the heated air passing through the air-cooled condenser (A) is supplied to the boiler (B) as combustion air.

Referring to FIG. 8, a waste heat recovery system 2000 to which a recompression Braaton cycle according to an embodiment of the present invention is applied includes a working fluid circulating line 2100 and a collecting line 2200.

The working fluid circulating line 2100 includes a first conveying line 2110, a second conveying line 2120, a third conveying line 2130, a fourth conveying line 2140, a fifth conveying line 2150, Transfer line 2160, seventh transfer line 2170, and eighth transfer line 2180.

The operating fluid that has been raised to a high temperature and a high pressure through the boiler B which is supplied with the fuel and the combustion air sucked from the outside by the pressurized blower and generates the combustion heat is delivered through the first transfer line 2110. The turbine of the generator (G) is operated by the working fluid thus conveyed. The exhaust gas discharged from the boiler (B) is discharged to the outside through the chimney. At this time, the working fluid is any one of water, carbon dioxide, and supercritical carbon dioxide, but is not limited thereto.

The working fluid discharged through the turbine is transferred to the first recuperator R1 through the second transfer line 2120. [ The working fluid discharged from the turbine is heat-exchanged through the first recuperator R1, and the temperature drops.

The working fluid heat exchanged through the first recuperator R1 is transferred to the second recuperator R2 through the third transfer line 2130. [ The working fluid subjected to the primary heat exchange through the first recuperator R1 is subjected to the secondary heat exchange in the second recuperator R2 and the temperature is lowered.

The working fluid heat exchanged through the second condenser R2 is transferred to the air-cooled condenser A through the fourth transfer line 2140. [ The working fluid passing through the air-cooled condenser (A) is cooled by the air cooler fan located at the front end of the air-cooled condenser (A).

The fifth conveyance line 2150 branches at the fourth conveyance line 2140 and is connected to the first condenser R1. At this time, the fifth transfer line 2150 is provided with a pump p. The working fluid thus conveyed is compressed by the pump p, the pressure rises, and the temperature rises while the heat is exchanged through the first recuperator R1.

The working fluid condensed through the air-cooled condenser (A) is transferred to the main pump (P) through the sixth transfer line (2160). The working fluid thus conveyed is compressed by the main pump P, and the pressure rises.

The working fluid compressed by the main pump P is transferred to the second condenser R2 through the seventh transfer line 2170. [ The temperature of the working fluid rises and is connected to the fifth conveyance line 2150 while being heat-exchanged through the second recuperator R2.

The working fluid to be heat-exchanged through the first recuperator R1 is transferred to the boiler B through the eighth transfer line 2180. [ As the boiler (B) reheats, the working fluid rises to high temperature and high pressure.

In the recovery line 2200, the air heated by the waste heat generated in the working fluid circulation line 2100 is recovered into the combustion air of the boiler B. The recovery line 2200 has a waste heat recovery line 2210 in which the heated air having passed through the air-cooled condenser A is supplied to the boiler B as combustion air.

When the air cooler fan located at the front end of the air-cooled condenser A rotates toward the air-cooled condenser A, the front-end side air of the air-cooled condenser A is heated while passing through the air-cooled condenser A Air raised by about 10 ° C to 20 ° C is generated through the rear end of the air-cooled condenser (A). The air with the raised temperature is recovered and supplied to the boiler (B) as combustion air. By using the air raised to about 10 to 20 DEG C through the waste heat recovery line 2210 as the combustion air of the boiler B, it is possible to save the fuel supplied to the boiler B, (B) increases. In addition, the system can be simplified by integrating the separately operated boiler (B) pressurized blower and the air-cooled condenser (A) air cooler fan into one.

9 is a diagram illustrating a waste heat recovery system to which a recompression Braaton cycle according to another embodiment of the present invention is applied. 9, the waste heat recovery line 2210 includes an oxygen sensor 2211, a flow rate control damper 2212, and a control unit 2213. The oxygen sensor 2211 measures the concentration of oxygen contained in the exhaust gas discharged from the boiler B. [ The flow rate control damper 2212 regulates the flow rate of the air conveyed through the waste heat recovery line 2210. The control unit 2213 controls the flow rate control damper 2212 in accordance with the oxygen concentration included in the exhaust gas measured by the oxygen sensor 2211.

When the concentration of oxygen contained in the exhaust gas discharged from the boiler B is measured to be higher or lower than the designed value, the efficiency is lowered due to the incomplete combustion of the boiler B. Therefore, the flow rate control damper 2212 is used to control the waste heat recovery line (2210).

10 is a diagram illustrating a waste heat recovery system to which a recompression Braaton cycle according to another embodiment of the present invention is applied. 10, the waste heat recovery line 2210 includes an oxygen sensor 2211, a flow rate control fan 2214, and a control unit 2215. The oxygen sensor 2211 measures the concentration of oxygen contained in the exhaust gas discharged from the boiler B. [ The flow rate regulating fan 2214 regulates the flow rate of the air delivered through the waste heat recovery line 2210. The control unit 2215 controls the rotational speed of the flow rate regulating fan 2214 according to the oxygen concentration contained in the exhaust gas measured by the oxygen sensor 2211.

When the concentration of oxygen contained in the exhaust gas discharged from the boiler B is measured to be higher or lower than the designed value, the efficiency is lowered due to the incomplete combustion of the boiler B, so that the rotational speed of the flow rate regulating fan 2214 is adjusted And controls the flow rate of the air recovered through the waste heat recovery line (2210).

11 is a diagram illustrating a waste heat recovery system and method using a recompression Braaton cycle according to another embodiment of the present invention. Referring to FIG. 11, in the waste heat recovery method using the recompression Braaton cycle according to another embodiment of the present invention, the recovery step includes a first branching step and a combustion air heating step.

In the first branching step, the working fluid is branched in the third feeding line 2130 and joined to the sixth feeding line 2160 through the heat dissipating portion H. [ In the combustion air heating step, the combustion air supplied to the boiler (B) is heated by the air passing through the heat dissipating portion (H).

Referring to FIG. 11, in the waste heat recovery system 2000 in which the recompression Braatton cycle according to another embodiment of the present invention is applied, the recovery line 2200 is configured such that the working fluid conveyed through the third conveyance line 2130 is two And a first branch line 2220 branched from between the first and second heat exchangers R1 and R2 and passing through the heat dissipating section H and then having a lowered temperature working fluid joining to the sixth transfer line 2160. [

The branch lines to be described later are not used to recover the air downstream of the air-cooled condenser A and supply the air to the combustion air of the boiler B, but a separate heat-radiating portion H may be provided in front of the boiler B in which the combustion air is sucked The working fluid circulating through the working fluid circulating line 2100 is partially branched and passes through the heat dissipating unit H and is then reconnected to the working fluid circulating line 2100.

The first branch line 2220 includes a temperature sensor 2221, a flow control valve 2222, and a control unit 2223. The temperature sensor 2221 measures the temperature of the air that has passed through the heat dissipating unit H to heat the combustion air supplied to the boiler B. [ The flow control valve 2222 regulates the flow rate of the working fluid delivered through the first branch line 2220. The control unit 2223 controls the flow rate regulating valve 2222 according to the temperature of the air measured by the temperature sensor 2221.

When the temperature of the combustion air supplied to the boiler B is higher than the designed value, the heat of combustion of the boiler B excessively rises and the boiler B may be overheated. If the temperature is measured to be low, The flow rate control valve 2222 is used to control the flow rate of the working fluid delivered through the first branch line 2220.

FIG. 12 is a diagram illustrating a waste heat recovery system and a method to which a recompression Braaton cycle according to another embodiment of the present invention is applied. Referring to FIG. 12, in the waste heat recovery method using a recompression Braaton cycle according to another embodiment of the present invention, the recovery step includes a second branching step and a combustion air heating step.

In the second branching step, the working fluid is branched in the third feeding line 2130 and joined to the fourth feeding line 2140 via the heat dissipating portion H. In the combustion air heating step, the combustion air supplied to the boiler (B) is heated by the air passing through the heat dissipating portion (H).

Referring to FIG. 12, in the waste heat recovery system 2000 in which the recompression Braaton cycle according to another embodiment of the present invention is applied, the recovery line 2200 is branched by the operation fluid conveyed through the third transfer line 2130 And a second branch line 2230 that passes through the heat dissipating portion H and then joins to the fourth transfer line 2140. This structure is for further cooling in the air-cooled condenser (A) when the temperature of the working fluid passing through the heat dissipating part (H) is not sufficiently lowered.

The second branch line 2230 includes a temperature sensor 2231, a flow control valve 2232, and a control unit 2233. The temperature sensor 2231 measures the temperature of the air that has passed through the heat dissipating unit H to heat the combustion air supplied to the boiler B. [ The flow control valve 2232 regulates the flow rate of the working fluid delivered through the second branch line 2230. The control unit 2233 controls the flow rate control valve 2232 in accordance with the temperature of the air measured by the temperature sensor 2231.

When the temperature of the combustion air supplied to the boiler B is higher than the designed value, the heat of combustion of the boiler B excessively rises and the boiler B may be overheated. If the temperature is measured to be low, The flow control valve 2232 is used to control the flow rate of the working fluid delivered through the second branch line 2230.

FIG. 13 is a diagram illustrating a waste heat recovery system and method using a recompression Braaton cycle according to another embodiment of the present invention. Referring to FIG. 13, in the waste heat recovery method using a recompression Braaton cycle according to another embodiment of the present invention, the recovery step includes a third branching step and a combustion air heating step.

In the third branching step, the working fluid is branched in the fifth transfer line 2150 and joined to the seventh transfer line 2170 via the heat dissipating portion H. In the combustion air heating step, the combustion air supplied to the boiler (B) is heated by the air passing through the heat dissipating portion (H).

Referring to FIG. 13, in the waste heat recovery system 2000 in which the recompression Braaton cycle according to another embodiment of the present invention is applied, the recovery line 2200 is branched from the working fluid conveyed through the fifth transfer line 2150 And a third branch line 2240 which joins the seventh transfer line 2170, which is the rear end of the main pump P, after passing through the heat dissipating unit H.

The third branch line 2240 includes a temperature sensor 2241, a flow rate control pump 2242, and a control unit 2243. The temperature sensor 2241 measures the temperature of the air that has passed through the heat dissipating unit H to heat the combustion air supplied to the boiler B. The flow regulation pump 2242 regulates the flow rate of the working fluid being conveyed through the third branch line 2240. The control unit 2243 controls the power of the flow rate adjusting pump 2242 in accordance with the temperature of the air measured by the temperature sensor 2241.

When the temperature of the combustion air supplied to the boiler B is higher than the designed value, the heat of combustion of the boiler B excessively rises and the boiler B may be overheated. If the temperature is measured to be low, Thereby controlling the flow rate of the working fluid delivered through the third branch line 2240 by regulating the power of the flow regulating pump 2242. [

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate description of the present invention and to facilitate understanding of the present invention and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

1000, 2000: Waste Heat Recovery System
1100, 2100: Working fluid circulation line
1110, 2110: first conveyance line 1120, 2120: second conveyance line
1130, 2130: third conveyance line 1140, 2140: fourth conveyance line
1150, 2150: fifth conveyance line 1160, 2160: sixth conveyance line
1200, and 2200: recovery lines 1210 and 2210: waste heat recovery line
1211, 2211: oxygen sensor 1212, 2212: flow rate control damper
1213, 1215, 1223, 1233, 1243, 1253, 2213, 2215, 2223, 2233, 2243:
1214, and 2214: flow rate adjusting fans 1220 and 2220: first branch line
1221, 1231, 1241, 1251, 2221, 2231, 2241: Temperature sensor
1222, 1232, 1242, 1252, 2222, 2232: Flow control valve
1230, 2230: second branch line 1240, 2240: third branch line
1250: Fourth branch line 1252, 2242: Flow regulating pump
2170: seventh conveyance line 2180: eighth conveyance line

Claims (26)

A first transfer line through which the working fluid heated by the boiler is transferred to operate the turbine of the generator, a second transfer line through which the working fluid discharged through the turbine is heat-exchanged in a recuperator, A third transfer line in which the heat exchanged working fluid is condensed in an air cooled condenser, a fourth transfer line in which the working fluid condensed through the air-cooled condenser is compressed by the main pump, A fifth transfer line in which the working fluid is heat-exchanged in the recuperator and a sixth transfer line in which the working fluid heat-exchanged through the recuperator is reheated in the boiler; And
A recovery line through which the air heated by the waste heat generated in the working fluid circulation line is recovered into the combustion air of the boiler;
/ RTI >
Wherein the recovery line includes a waste heat recovery line through which heated air having passed through the air-cooled condenser is supplied to the boiler as combustion air. delete The method according to claim 1,
The waste heat recovery line includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler;
A flow rate control damper in which the flow rate of the air delivered through the waste heat recovery line is adjusted; And
A control unit in which the flow rate control damper is controlled according to an oxygen concentration included in exhaust gas measured through the oxygen sensor; The waste heat recovery system comprising: The method according to claim 1,
The waste heat recovery line includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler;
A flow regulating fan in which the flow rate of the air delivered through the waste heat recovery line is regulated; And
A controller for controlling the rotational speed of the flow rate adjusting fan according to the concentration of oxygen contained in the exhaust gas measured through the oxygen sensor; The waste heat recovery system comprising: A first transfer line through which the working fluid heated by the boiler is transferred to operate the turbine of the generator, a second transfer line through which the working fluid discharged through the turbine is heat-exchanged in a recuperator, A third transfer line in which the heat exchanged working fluid is condensed in an air cooled condenser, a fourth transfer line in which the working fluid condensed through the air-cooled condenser is compressed by the main pump, A fifth transfer line in which the working fluid is heat-exchanged in the recuperator and a sixth transfer line in which the working fluid heat-exchanged through the recuperator is reheated in the boiler; And
A recovery line through which the air heated by the waste heat generated in the working fluid circulation line is recovered into the combustion air of the boiler;
/ RTI >
Wherein the recovery line includes a branch line branched from the working fluid circulation line and connected to the working fluid circulation line via the heat dissipation unit,
Wherein the branch line includes a temperature sensor for measuring a temperature of air passing through the heat dissipation unit to heat combustion air supplied to the boiler;
A flow control valve through which the flow rate of the working fluid fed through the branch line is adjusted; And
And a control unit for controlling the flow rate control valve according to a temperature of air measured through the temperature sensor. 6. The method of claim 5,
Wherein the branch line is branched at the second transfer line and connected to the fourth transfer line via the heat dissipation unit. 6. The method of claim 5,
Wherein the branch line branches at the third transfer line and is connected to the third transfer line or the fourth transfer line via the heat dissipation unit. 6. The method of claim 5,
Wherein the branch line is branched at the sixth transfer line and connected to the fifth transfer line via the heat dissipation unit. A first transfer line through which the working fluid heated by the boiler is transferred to operate the turbine of the generator, a second transfer line through which the working fluid discharged through the turbine is heat-exchanged in the first recuperator, A fourth transfer line through which the working fluid heat-exchanged through the second condenser is heat-exchanged in the second condenser, a fourth transfer line through which the working fluid heat-exchanged through the second condenser is condensed in the air-cooled condenser, A sixth transfer line connected to the first recuperator and having a pump, a sixth transfer line in which the working fluid condensed through the air-cooled condenser is compressed by the main pump, a working fluid compressed by the main pump The seventh transfer line connected to the fifth transfer line and the working fluid heat-exchanged through the first recuperator are reheated in the boiler, A working fluid circulation line having a transfer line; And
A recovery line through which the air heated by the waste heat generated in the working fluid circulation line is recovered into the combustion air of the boiler;
The waste heat recovery system comprising: 10. The method of claim 9,
Wherein the recovery line is a waste heat recovery line in which heated air passing through the air-cooled condenser is supplied to the boiler as combustion air; The waste heat recovery system comprising: 11. The method of claim 10,
The waste heat recovery line includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler;
A flow rate control damper in which the flow rate of the air delivered through the waste heat recovery line is adjusted; And
A control unit in which the flow rate control damper is controlled according to an oxygen concentration included in exhaust gas measured through the oxygen sensor; The waste heat recovery system comprising: 11. The method of claim 10,
The waste heat recovery line includes an oxygen sensor for measuring the concentration of oxygen contained in the exhaust gas discharged from the boiler;
A flow regulating fan in which the flow rate of the air delivered through the waste heat recovery line is regulated; And
A controller for controlling the rotational speed of the flow rate adjusting fan according to the concentration of oxygen contained in the exhaust gas measured through the oxygen sensor; The waste heat recovery system comprising: 10. The method of claim 9,
A first branch line branched from the third transfer line and connected to the sixth transfer line via a heat dissipation unit; / RTI >
Wherein the first branch line includes a temperature sensor for measuring a temperature of air passing through the heat dissipating unit to heat combustion air supplied to the boiler;
A flow control valve through which the flow rate of the working fluid fed through the first branch line is adjusted; And
A control unit for controlling the flow rate control valve according to a temperature of air measured through the temperature sensor; The waste heat recovery system comprising: 10. The method of claim 9,
A second branch line branched from the third transfer line and connected to the fourth transfer line via a heat dissipation unit; / RTI >
Wherein the second branch line includes a temperature sensor for measuring the temperature of air passing through the heat dissipation unit to heat the combustion air supplied to the boiler;
A flow control valve through which the flow rate of the working fluid delivered through the second branch line is adjusted; And
A control unit for controlling the flow rate control valve according to a temperature of air measured through the temperature sensor; The waste heat recovery system comprising: 10. The method of claim 9,
A third branch line branched at the fifth transfer line and connected to the seventh transfer line via the heat dissipation unit; / RTI >
Wherein the third branch line includes a temperature sensor for measuring a temperature of air passing through the heat dissipation unit to heat the combustion air supplied to the boiler;
A flow regulation pump in which a flow rate of a working fluid transferred through the third branch line is adjusted; And
A controller for controlling power of the flow rate adjusting pump according to the temperature of the air measured through the temperature sensor; The waste heat recovery system comprising: A power generation step in which a working fluid heated by a boiler is transferred through a first transfer line to operate a turbine of a generator, and a working fluid discharged through the turbine is transferred through a second transfer line to perform a primary heat exchange in a recuperator A condensing step in which the working fluid, which has undergone the primary heat exchange through the heat exchanger, is conveyed through a third conveying line and condensed in an air-cooled condenser; and a working fluid condensed through the air- A second heat exchange step in which the working fluid compressed by the main pump is transferred through a fifth transfer line and subjected to secondary heat exchange in the recuperator, And a reheating step in which the heat exchanged working fluid is transferred through the sixth transfer line and reheated in the boiler; And
A recovery step of recovering air heated by waste heat generated in the working fluid circulation step to the combustion air of the boiler;
/ RTI >
Wherein the recovering step includes a waste heat recovery step in which heated air passing through the air-cooled condenser is supplied to the boiler as combustion air. delete A power generation step in which a working fluid heated by a boiler is transferred through a first transfer line to operate a turbine of a generator, and a working fluid discharged through the turbine is transferred through a second transfer line to perform a primary heat exchange in a recuperator A condensing step in which a working fluid that has undergone a primary heat exchange through the heat exchanger is conveyed through a third conveyance line and is condensed in an air-cooled condenser; and a working fluid condensed through the air- A second heat exchange step in which the working fluid compressed by the main pump is transferred through a fifth transfer line and subjected to secondary heat exchange in the recuperator, And a reheating step in which the second heat exchanged working fluid is transferred through the sixth transfer line and reheated in the boiler; And
A recovery step of recovering air heated by waste heat generated in the working fluid circulation step to the combustion air of the boiler;
/ RTI >
Wherein the recovering step comprises branching the working fluid in the second conveying line or the third conveying line and branching the working fluid to the fourth conveying line via the heat dissipating unit; And
Heating the combustion air supplied to the boiler by air passing through the heat dissipation unit; . delete A power generation step in which a working fluid heated by a boiler is transferred through a first transfer line to operate a turbine of a generator, and a working fluid discharged through the turbine is transferred through a second transfer line to perform a primary heat exchange in a recuperator A condensing step in which a working fluid that has undergone a primary heat exchange through the heat exchanger is conveyed through a third conveyance line and is condensed in an air-cooled condenser; and a working fluid condensed through the air- A second heat exchange step in which the working fluid compressed by the main pump is transferred through a fifth transfer line and subjected to secondary heat exchange in the recuperator, And a reheating step in which the second heat exchanged working fluid is transferred through the sixth transfer line and reheated in the boiler; And
A recovery step of recovering air heated by waste heat generated in the working fluid circulation step to the combustion air of the boiler;
/ RTI >
A third branching step in which the working fluid in the third transfer line is branched and rejoined to the third transfer line via the heat dissipating unit; And
Heating the combustion air supplied to the boiler by air passing through the heat dissipation unit; . A power generation step in which a working fluid heated by a boiler is transferred through a first transfer line to operate a turbine of a generator, and a working fluid discharged through the turbine is transferred through a second transfer line to perform a primary heat exchange in a recuperator A condensing step in which a working fluid that has undergone a primary heat exchange through the heat exchanger is conveyed through a third conveyance line and is condensed in an air-cooled condenser; and a working fluid condensed through the air- A second heat exchange step in which the working fluid compressed by the main pump is transferred through a fifth transfer line and subjected to secondary heat exchange in the recuperator, And a reheating step in which the second heat exchanged working fluid is transferred through the sixth transfer line and reheated in the boiler; And
A recovery step of recovering air heated by waste heat generated in the working fluid circulation step to the combustion air of the boiler;
/ RTI >
Wherein the recovering step comprises a fourth branching step in which the working fluid in the sixth conveying line is branched and joined to the fifth conveying line via the heat radiating part; And
Heating the combustion air supplied to the boiler by air passing through the heat dissipation unit; . A power generation step in which a working fluid heated by a boiler is conveyed through a first conveyance line to operate a turbine of a generator, and a working fluid discharged through the turbine is conveyed through a second conveyance line, A second heat exchange step in which the working fluid subjected to the primary heat exchange through the first recuperator is conveyed through the third conveyance line and subjected to secondary heat exchange in the second recuperator, A condensing step in which the working fluid subjected to the secondary heat exchange is transferred through the fourth transfer line and condensed in the air-cooled condenser, and the second transfer line is branched from the fourth transfer line and conveyed through the fifth transfer line, A third heat exchange step of performing tertiary heat exchange in the recuperator, a compressing step in which the working fluid condensed through the air-cooled condenser is transferred through the sixth transfer line and compressed by the main pump, Wherein the working fluid compressed by the pump is transferred through a seventh transfer line to be tertiary heat exchanged in the second recuperator and then joined to the fifth transfer line and a heat exchanged operation through the first recuperator A reheating step in which the fluid is conveyed through the eighth conveyance line and reheated in the boiler; And
A recovery step of recovering air heated by waste heat generated in the working fluid circulation step to the combustion air of the boiler;
. 23. The method of claim 22,
Wherein the recovering step comprises: a waste heat recovery step in which heated air passing through the air-cooled condenser is supplied to the boiler as combustion air; . 23. The method of claim 22,
Wherein the recovery step includes a first branching step in which the working fluid in the third transfer line is branched and joined to the sixth transfer line via the heat dissipation part; And
Heating the combustion air supplied to the boiler by air passing through the heat dissipation unit; . 23. The method of claim 22,
Wherein the recovering step includes a second branching step in which the working fluid in the third conveying line is branched and joined to the fourth conveying line via the heat radiating part; And
Heating the combustion air supplied to the boiler by air passing through the heat dissipation unit; . 23. The method of claim 22,
Wherein the recovering step includes a third branching step in which the working fluid in the fifth conveying line is branched and joined to the seventh conveying line via the heat radiating part; And
Heating the combustion air supplied to the boiler by air passing through the heat dissipation unit; .

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