KR20150086782A - Cogeneration Plant Cooling System - Google Patents

Abstract

According to an embodiment of the present invention, a cooling system for a cogeneration unit comprises: a turbine which operates by steam; a condenser which liquefies steam included in the system′s water that enters through a path connected with the turbine and passes the turbine; and a circulation pipeline which penetrates the condenser, and circulates cooling water for liquefying at least a part of the steam included in the system′s water. Therefore, the cooling system for a cogeneration unit can improve the entire efficiency of a cogeneration unit and can efficiently operate the condenser placed in the cogeneration unit.

Description

[0001] Cogeneration Plant Cooling System [

An embodiment of the present invention relates to a cogeneration power plant cooling system which is equipped with a heat pump in a cogeneration facility to improve the efficiency of the entire cogeneration plant and can efficiently operate the condenser provided in the cogeneration facility .

The contents described in this section merely provide background information on the embodiment of the present invention and do not constitute the prior art.

Generally, a cogeneration facility is a type of power generation facility that produces electricity through power generation facilities, produces hot water using power generation facilities, and supplies hot water to places where hot water such as district heating demand is needed. That is, the cogeneration facility is a power generation facility that produces electricity and heat at the same time.

The heat generated by the cogeneration facility is called process heat, and the process heat can be generated by extracting heat from the condenser provided in the power plant system. In addition, the process heat may be produced in various ways such as a method of producing hot water by heating a large amount of water by adding a portion of high temperature steam from a boiler or steam turbine provided in a power plant system, or the like.

On the other hand, the heat pump transfers heat from a low-temperature heat source to a high-temperature heat source by injecting work, and thus the effect of cooling the low-temperature heat source may occur. Lt; / RTI >

Therefore, the embodiment of the present invention provides a cogeneration system cooling system capable of improving the efficiency of the entire cogeneration system and providing efficient operation of the condensers provided in the cogeneration system by providing a heat pump in the cogeneration system The purpose is to provide.

The technical object of the present invention is not limited to the above-mentioned technical objects and other technical objects which are not mentioned can be clearly understood by those skilled in the art from the following description will be.

One embodiment of a cogeneration plant cooling system includes a turbine driven by steam; A condenser in which the steam contained in the systematic water passing through the turbine flowing through the passage connected to the turbine is liquefied; A circulation piping line passing through the condenser and circulating the circulating cooling water for liquefying at least a part of the steam contained in the systematic water; A cooling tower installed in the circulation pipe line for cooling the circulation cooling water that has passed through the condenser; A cooling water piping line through which water is supplied to the circulation piping line from an external cooling water supply source or at least a part of the water flows from the circulation piping line; A water supply pipe line connecting the circulation pipe line and the cooling water pipe line to supply water from the cooling water pipe line to the circulation pipe line; A return pipe line connecting the circulation pipe line and the cooling water pipe line and sending at least a portion of the water from the circulation pipe line to the cooling water pipe line; A first heat pump installed in the cooling raw water pipe line for extracting heat from water passing through the cooling raw water pipe line; And a second heat pump installed in the return pipe line for extracting heat from the water passing through the return pipe line.

The water supply line may be connected to the circulation line between the outlet of the cooling tower and the outlet of the circulation line.

The first heat pump and the second heat pump may be absorption heat pumps including an absorber, a regenerator, a condenser and an evaporator.

The first heat pump and the second heat pump may be driven by surplus steam added from the turbine.

One embodiment of the cogeneration system cooling system includes a first valve installed between a point branched from the cooling water pipe line of the water supply pipe line and a point connected to the circulation pipe line; A second valve installed between the cooling tower outlet point of the circulation pipe line and a point where the water supply pipe line and the circulation pipe line are connected; A third valve installed between a point where the return pipe line of the circulation pipe line branches and an inlet point of the cooling tower; And a fourth valve installed in the return pipe line.

The first valve and the fourth valve are closed and the second valve and the third valve are opened to operate the cooling tower and the system water passing through the turbine by the water flowing through the circulation pipeline It may be to liquefy at least a portion of the vapor.

When the temperature difference between the average temperature of the water flowing through the portion of the circulation pipeline passing through the condenser and the average temperature of the systematic water contained in the condenser falls below a set value, the first valve and the fourth valve are opened, And increase the flow rate of water flowing through the portion of the circulation pipeline that passes through the condenser.

Wherein when the cooling tower is tripped, the first valve and the fourth valve are opened, the second valve and the third valve are closed, and the water is passed through the turbine by the water flowing through the water supply pipe line and the return pipe line And to liquefy at least a part of the steam contained in the systematic water.

Closing the second valve and the third valve, opening the first valve and the fourth valve, bypassing the cooling tower, passing the turbine by the water flowing through the water supply line and the return line, And to liquefy at least a part of the steam contained in the systematic water.

The second valve and the third valve are opened when the temperature difference between the average temperature of the water flowing through the portion of the circulation pipeline passing through the condenser and the average temperature of the systematic water contained in the condenser falls below a set value, The cooling tower may be operated to increase the flow rate of the water flowing through the portion of the circulation pipeline that passes through the condenser.

When at least one of the water supply pipe line and the return pipe line is tripped, the second valve and the third valve are opened, the first valve and the fourth valve are closed, the cooling tower is operated, And to liquefy at least a part of the steam contained in the systematic water passing through the turbine by the water flowing through the piping line.

Wherein the first valve, the second valve, the third valve, and the fourth valve are provided as valves capable of controlling the flow rate, and the cooling tower is operated, and the average temperature of water flowing through the portion of the circulation pipeline, A second valve, a third valve, and a fourth valve so as to prevent the temperature difference between the average temperature of the systematic water accommodated in the condenser from falling below a set value, To control the flow rate.

The first heat pump may be installed between an inlet of the cooling water pipe line and a point where the water pipe line branches.

The cooling water piping line is connected to an industrial water supply source from a cooling water supply source. Water flowing into the cooling water supply line from the cooling water supply source is cooled by the first heat pump and cooled by the second heat pump It may be combined with the water introduced from the return pipeline line and sent to the use place of the industrial water through the cooling raw water pipeline.

Further comprising a first circuit piping line connecting the first heat pump and the district heating consumer, wherein the heated water from the first heat pump is supplied to the district heating consumer through the first circuit piping line, And the water cooled through the heat demanding part may be recovered to the first heat pump through the first circuit piping line.

Further comprising a second circuit piping line connecting the second heat pump and the district heating consumer, wherein the heated water from the second heat pump is supplied to the district heating consumer through the second circuit pipeline, And the water cooled through the heat demanding part may be recovered to the second heat pump through the second circuit piping line.

The cooling tower may include a plurality of cooling towers, and the temperature of the water flowing out of the cooling tower may sequentially drop as each of the cooling towers is sequentially operated.

The cogeneration system cooling system of the above-described embodiment has a heat pump in the cogeneration system to improve the efficiency of the entire cogeneration system and to efficiently operate the condenser provided in the cogeneration system.

In addition, in the cogeneration system cooling system of the embodiment, water is condensed efficiently in the condenser because the circulation pipe line in which the cooling tower is operated, the water supply pipe line in which the cooling water flows and the return pipe line are used together in the condenser, Line and the return piping line are tripped, it is possible to stably operate the condenser.

1 is a schematic view showing a cogeneration system cooling system according to an embodiment of the present invention.
2 is a flowchart illustrating a method of operating a cogeneration system facility cooling system in a case where a circulation pipeline is mainly operated in a cogeneration system cooling system according to an embodiment of the present invention.
3 is a flowchart illustrating a method of operating a cogeneration system facility cooling system in a case where a water supply pipeline line and a return pipeline line are mainly operated in the cogeneration system cooling system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms specifically defined in consideration of the constitution and operation of the present invention are only for explaining the embodiments of the present invention, and do not limit the scope of the present invention.

1 is a schematic view showing a cogeneration system cooling system according to an embodiment of the present invention. The cogeneration system cooling system includes a turbine 10, a condenser 20, a cooling tower 30, a first heat pump 40 and a second heat pump 50. The cogeneration system cooling system includes a circulation piping line 100, a cooling raw water piping line 200, a water supply piping line 300, a return piping line 400, a steam inflow piping 500, a first additional piping line 510, a second additional piping line 520, a first circuit piping line 610, and a second circuit piping line 620.

The turbine 10 includes at least a part of steam through the steam inflow pipe 500 and is mainly driven by the steam contained in the systematic water by receiving the systematic water circulating through the cogeneration system (not shown). The cogeneration system may be any type of cogeneration system that produces electricity and heat simultaneously, such as the Rankine cycle system, the gas turbine (10) system, and the combined cycle power system. Meanwhile, the cogeneration system cooling system according to an embodiment of the present invention can be seen as a part of the cogeneration system.

In the condenser 20, the steam contained in the system water passing through the turbine 10 flowing through the passage connected to the turbine 10 is liquefied. The systematic water coming out through the outlet of the condenser 20 is in a liquid state, and the systematic water of this liquid circulates through the cogeneration facility again through a circulation feed water pump (not shown). The circulating cooling water flowing through the circulation piping line 100 passing through the condenser 20 serves to liquefy the steam contained in the system water.

The cooling tower 30 is installed in the circulation piping line 100 and cools the circulation cooling water that has passed through the condenser 20. The plurality of cooling towers 30 are provided so that the temperature of the water flowing out of the cooling tower 30 sequentially drops as each of the cooling towers 30 is sequentially operated so that the temperature of the circulating cooling water in the condenser 20 can be adjusted So that the condenser 20 can effectively liquefy the vapor.

The first heat pump 40 is installed in the cooling water piping line 200 and may be installed between the inlet of the cooling water piping line 200 and the point where the water piping line 300 branches.

 The heat is extracted from the water passing through the cooling raw water piping line 200, that is, the cooling raw water. Therefore, the cooling raw water passing through the cooling raw water piping line 200 is cooled by the first heat pump 40. The heat extracted by the first heat pump (40) is supplied to the district heating consumer (2). To this end, the cogeneration system cooling system further includes a first circuit piping line 610 connecting the first heat pump 40 and the district heating consumer 2, Is supplied to the district heating consumer 2 through the first circuit piping line 610 and the water cooled through the district heating consumer 2 is supplied to the first heat pump 40 through the first circuit piping line 610, . On the other hand, the cooling raw water cooled by the first heat pump 40 flows into the condenser 20, so that the condenser 20 can more efficiently perform liquefaction of the vapor.

The second heat pump 50 is installed in the return piping line 400 and extracts heat from the water passing through the return piping line 400. Thus, the water passing through the return piping line 400 is cooled by the second heat pump 50. The heat extracted by the second heat pump (50) is supplied to the district heating consumer (2). To this end, the cogeneration system cooling system further includes a second circuit piping line 620 connecting the second heat pump 50 and the district heating consumer 2, Is supplied to the district heating consumer 2 through the second circuit piping line 620 and the water cooled through the district heating consumer 2 is supplied to the second heat pump 50 through the second circuit piping line 620. [ .

The first heat pump 40 and the second heat pump 50 may be provided with an absorption heat pump including an absorber, a regenerator, a condenser, and an evaporator. Since the absorption heat pump can effectively utilize the waste heat and the waste heat can be easily obtained in the cogeneration facility, it is more advantageous to use the absorption heat pump than the other type heat pump in the cogeneration system cooling system considering the energy efficiency. . The specific structure of the absorption type heat pump is generally known, and a detailed description thereof will be omitted.

The turbine 10 and the first heat pump 40 are connected to each other by a first additional piping line 510 and the turbine 10 and the second heat pump 50 are connected to each other by a second additional piping line 520 The first heat pump 40 and the second heat pump 50 may be provided to be driven by the steam added from the turbine 10. [ When the heat pump is driven by electricity, there is a disadvantage that the generated electricity is consumed in the cogeneration system. Therefore, it is more advantageous to drive the heat pump by using the steam considering the energy efficiency.

The circulation piping line 100 is provided through the condenser 20 and circulates the circulating cooling water for liquefying at least a part of the steam contained in the systematic water. The circulating cooling water receives heat from the system water in the condenser 20, and the temperature rises, and is cooled again while passing through the cooling tower 30.

The cooling raw water pipe line 200 supplies water to the circulation pipe line 100 from the external cooling water supply source 3 or at least part of the water flows into the circulation pipe line 100. The source of cooling water (3) can be anywhere, such as a river, a reservoir, and the sea, as long as it can supply cooling water used for cogeneration facilities.

The cooling water piping line 200 is connected from the cooling water source supply source 3 to the industrial water use place 1 and the water flowing into the cooling raw water pipe line 200 from the cooling water source supply source 3 is supplied to the first heat pump 40 And is sent to the industrial water use place 1 through the cooling water piping line 200 after being combined with the water introduced from the return piping line 400 that is cooled by the first heat pump 50 and cooled by the second heat pump 50. Therefore, the water passing through the cooling raw water piping line 200 is cooled by the first heat pump 40 and the second heat pump 50 and sent to the industrial water use place 1, which is somewhat lower than the room temperature water To supply the water required for industrial or industrial equipment requiring water at a temperature.

The water supply piping line 300 connects the circulation piping line 100 and the cooling raw water piping line 200 and supplies water to the circulation piping line 100 from the cooling raw water piping line 200. The water supply pipe line 300 may be connected to the circulation pipe line 100 between the outlet point of the cooling tower 30 of the circulation pipe line 100 and the point where the condenser 20 is connected.

The return piping line 400 connects the circulation piping line 100 and the cooling raw water piping line 200 and sends at least a portion of the water from the circulation piping line 100 to the cooling water piping line 200.

The cogeneration system cooling system may include a first valve 61, a second valve 62, a third valve 63, and a fourth valve 64.

The first valve 61 is installed between a point branched from the cooling water pipe line 200 of the water supply pipe line 300 and a point connected to the circulation pipe line 100. The second valve 62 is installed between the exit point of the cooling tower 30 of the circulation pipeline 100 and the point where the circulation pipeline 100 is connected to the water supply line 300. The third valve 63 is installed between a point where the return pipe line 400 of the circulation pipe line 100 branches and an inlet point of the cooling tower 30. A fourth valve (64) is installed in the return line (400).

The first valve 61, the second valve 62, the third valve 63 and the fourth valve 64 are provided as valves capable of flow control and operate the cooling tower 30, The first valve 61 and the second valve 61 are arranged such that the temperature difference DELTA T between the average temperature of the water flowing through the condenser 20 of the condenser 20 and the average temperature of the systematic water accommodated in the condenser 20 does not fall below the set value, The third valve 63 and the fourth valve 64 can control the flow rate of the water flowing through the portion of the circulation pipeline 100 which passes through the condenser 20. The flow control using each valve can be implemented by a general control system including an on-line method.

The set value relating to the temperature difference DELTA T is determined by the flow rate of the systematic water flowing into the condenser 20, the flow rate of water flowing through the circulation piping line 100 passing through the condenser 20, the pump (not shown) So that the liquefaction of the steam can be efficiently performed. For example, the set value may be set at 10 캜 to 15 캜.

On the other hand, only a part of the first valve 61, the second valve 62, the third valve 63 and the fourth valve 64 is opened so that the circulation pipeline 100 is operated mainly, Or the main piping line 300 and the return piping line 400 may be operated to liquefy the steam contained in the system water. A method of operating the cogeneration system cooling system will be described below with reference to FIGS. 2 and 3. FIG.

2 is a flowchart illustrating a method of operating a cogeneration system cooling system in a case where a circulation pipeline 100 is operated mainly in a cogeneration system cooling system according to an embodiment of the present invention.

The first valve 61 and the fourth valve 64 are closed and the second valve 62 and the third valve 63 are opened and the cooling tower 30 is opened And liquefies at least a portion of the steam contained in the system water that has passed through the turbine 10 by the water flowing through the circulation piping line 100.

At this time, the temperature difference (? T) between the average temperature of the water flowing through the portion of the circulation pipeline (100) passing through the condenser (20) and the average temperature of the system water accommodated in the condenser (20) is measured. The temperature difference DELTA T measurement can be performed by a temperature measuring sensor (not shown) installed at a site passing through the condenser 20 of the condenser 20 and the circulating pipeline 100.

Next, the measured temperature difference? T is compared with the set value. When the temperature difference? T falls below the set value, the first valve 61 and the fourth valve 64 are opened and the water line 300 and the return piping line 400 are operated to increase the flow rate of the water flowing through the portion of the circulation pipeline 100 passing through the condenser 20 so that the temperature difference ΔT can be recovered to a state exceeding the set value have.

On the other hand, when a trip occurs in which the operation of the cooling tower 30 is stopped due to a failure of the cooling tower 30, the first valve 61 and the fourth valve 64 are opened and the second valve 62 and the 3 valve 63 is closed to liquefy at least a part of the steam contained in the system water that has passed through the turbine 10 by the water flowing through the water supply pipe line 300 and the return pipe line 400. Therefore, even when the cooling tower 30 is tripped, the water supply pipe line 300 and the return pipe line 400 operate, so that the condenser 20 can operate normally.

3 is a flowchart illustrating a method of operating a cogeneration system facility cooling system in a case where a water supply line 300 and a return line 400 operate mainly in a cogeneration system cooling system according to an embodiment of the present invention.

The second valve 62 and the third valve 63 are closed and the first valve 61 and the fourth valve 64 are opened when the water supply line 300 and the return line 400 are operated mainly And at least a part of the steam contained in the system water passed through the turbine 10 by the water flowing through the water supply pipe line 300 and the return pipe line 400 is liquefied without operating the cooling tower 30.

At this time, the average temperature of the water flowing through the portion of the circulation pipe line 100 connected to the water supply pipe line 300 and the return pipe line 400 and the average temperature of the system water accommodated in the condenser 20 And the temperature difference DELTA T is measured.

Next, the measured temperature difference? T is compared with the set value. When the temperature difference? T falls below the set value, the second valve 62 and the third valve 63 are opened and the cooling tower 30 is opened. To increase the flow rate of the water flowing through the portion of the circulation pipeline 100 that passes through the condenser 20 so that the temperature difference DELTA T can be recovered to a state exceeding the set value.

On the other hand, when a trip occurs in which the operation of the water supply line 300 connected to the cooling water piping line 200 is stopped due to the failure of the first heat pump 40 or the like, The second valve 62 and the third valve 63 are opened and the first valve 61 and the fourth valve 64 are closed in at least one of the cases where the return pipe line 400 is tripped due to failure, And operates the cooling tower 30 to liquefy at least a part of the steam contained in the system water that has passed through the turbine 10 by the water flowing through the circulation pipeline line 100. Accordingly, even when at least one of the water supply line 300 and the return pipe line 400 is tripped, the cooling tower 30 and the circulation pipe line 100 operate, so that the condenser 20 can operate normally.

While only a few are described above in connection with the embodiments of the present invention, various other forms of implementation are possible. The technical contents of the embodiments described above may be combined in various forms other than the mutually incompatible technologies, and may be implemented in a new embodiment through the same.

1: Industrial water use place 2: District heating demand place
3: Cooling water supply source 10: Turbine
20: condenser 30: cooling tower
40: first heat pump 50: second heat pump
61: first valve 62: second valve
63: third valve 64: fourth valve
100: Circulating piping line 200: Cooling raw water piping line
300: Water piping line 400: Return piping line
500: steam inlet pipe 510: first additional pipe line
520: second additional piping line 610: first circuit piping line
620: Second circuit piping line ΔT: Temperature difference

Claims (17)

Steam driven turbines;
A condenser in which the steam contained in the systematic water passing through the turbine flowing through the passage connected to the turbine is liquefied;
A circulation piping line passing through the condenser and circulating the circulating cooling water for liquefying at least a part of the steam contained in the systematic water;
A cooling tower installed in the circulation pipe line for cooling the circulation cooling water that has passed through the condenser;
A cooling water piping line through which water is supplied to the circulation piping line from an external cooling water supply source or at least a part of the water flows from the circulation piping line;
A water supply pipe line connecting the circulation pipe line and the cooling water pipe line to supply water from the cooling water pipe line to the circulation pipe line;
A return pipe line connecting the circulation pipe line and the cooling water pipe line and sending at least a portion of the water from the circulation pipe line to the cooling water pipe line;
A first heat pump installed in the cooling raw water pipe line for extracting heat from water passing through the cooling raw water pipe line; And
A second heat pump installed in the return pipe line for extracting heat from water passing through the return pipe line,
And a cogeneration system cooling system. The method according to claim 1,
Wherein the water supply pipe line
Wherein the circulation piping line is connected to the circulation piping line between the cooling tower outlet point of the circulation piping line and the point of connection with the condenser. 3. The method of claim 2,
Wherein the first heat pump and the second heat pump comprise:
An absorber, an absorber, a regenerator, a condenser and an evaporator. 3. The method of claim 2,
Wherein the first heat pump and the second heat pump comprise:
And is driven by surplus steam added from the turbine. 3. The method of claim 2,
A first valve installed between a point branched from the cooling water pipe line of the water supply pipe line and a point connected to the circulation pipe line;
A second valve installed between the cooling tower outlet point of the circulation pipe line and a point where the water supply pipe line and the circulation pipe line are connected;
A third valve installed between a point where the return pipe line of the circulation pipe line branches and an inlet point of the cooling tower; And
A fourth valve installed in the return pipe line;
Further comprising: a cryogenic power plant cooling system. 6. The method of claim 5,
The first valve and the fourth valve are closed and the second valve and the third valve are opened to operate the cooling tower and the system water passing through the turbine by the water flowing through the circulation pipeline Wherein at least a portion of the vapor is liquefied. The method according to claim 6,
When the temperature difference between the average temperature of the water flowing through the portion of the circulation pipeline passing through the condenser and the average temperature of the systematic water contained in the condenser falls below a set value, the first valve and the fourth valve are opened, And increases the flow rate of water flowing through a portion of the circulation pipeline that passes through the condenser. The method according to claim 6,
Wherein when the cooling tower is tripped, the first valve and the fourth valve are opened, the second valve and the third valve are closed, and the water is passed through the turbine by the water flowing through the water supply pipe line and the return pipe line And at least a part of the steam contained in said systematic liquor is liquefied. 6. The method of claim 5,
Closing the second valve and the third valve, opening the first valve and the fourth valve, bypassing the cooling tower, passing the turbine by the water flowing through the water supply line and the return line, And at least a part of the steam contained in said systematic liquor is liquefied. 10. The method of claim 9,
The second valve and the third valve are opened when the temperature difference between the average temperature of the water flowing through the portion of the circulation pipeline passing through the condenser and the average temperature of the systematic water contained in the condenser falls below a set value, Wherein the cooling tower is operated to increase the flow rate of water flowing through a portion of the circulation pipeline that passes through the condenser. 10. The method of claim 9,
When at least one of the water supply pipe line and the return pipe line is tripped, the second valve and the third valve are opened, the first valve and the fourth valve are closed, the cooling tower is operated, And the liquefying unit is configured to liquefy at least a part of the steam contained in the systematic water that has passed through the turbine by the water flowing through the piping line. 6. The method of claim 5,
Wherein the first valve, the second valve, the third valve, and the fourth valve are provided as valves capable of controlling the flow rate, and the cooling tower is operated, and the average temperature of water flowing through the portion of the circulation pipeline, A second valve, a third valve, and a fourth valve so as to prevent the temperature difference between the average temperature of the systematic water accommodated in the condenser from falling below a set value, And the flow rate of the cooling water is controlled. The method according to claim 1,
The first heat pump includes:
Wherein the cooling water is installed between an inlet of the cooling raw water pipe line and a point where the water supply pipe line is branched. The method according to claim 1,
The cooling water piping line is connected to an industrial water supply source from a cooling water supply source. Water flowing into the cooling water supply line from the cooling water supply source is cooled by the first heat pump and cooled by the second heat pump Wherein the cooling water is sent to the use place of the industrial water through the cooling water piping line in combination with the water introduced from the return piping line. The method according to claim 1,
Further comprising a first circuit piping line connecting the first heat pump and the district heating consumer, wherein the heated water from the first heat pump is supplied to the district heating consumer through the first circuit piping line, And the water cooled through the heat consumer is recovered to the first heat pump through the first circuit piping line. The method according to claim 1,
Further comprising a second circuit piping line connecting the second heat pump and the district heating consumer, wherein the heated water from the second heat pump is supplied to the district heating consumer through the second circuit pipeline, And the water cooled through the heating consumer is recovered to the second heat pump through the second circuit piping line. The method according to claim 1,
The cooling tower comprises:
And the temperature of the water flowing out of the cooling tower sequentially drops as the respective cooling towers are sequentially operated.

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