KR101728263B1 - Boiler operation method and boiler - Google Patents

Abstract

The boiler according to the present invention includes a water supply system 11 through which boiler water flows, an ammonia addition unit 12 for adding ammonia solution to the boiler water, a pH measurement unit 14 for measuring the pH of the boiler water and a control unit 15 Respectively. The controller 15 controls the ammonia addition unit 12 so that the pH of the boiler water is included in the storage pH range when the boiler water is heated and controls the pH of the boiler water before the boiler water stops flowing through the water supply system 11 The ammonia addition unit 12 is controlled so that it is contained in the storage pH range. At this time, the arbitrary pH included in the storage pH range is larger than the arbitrary pH included in the operating pH range. Such a boiler can more easily prevent the water supply system 11 from corroding compared to filling the water supply system 11 with storage boiler water containing hydrazine.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a boiler,

The present invention relates to a boiler operating method and a boiler, and more particularly to a boiler operating method and a boiler used for storing a water supply system in which boiler water circulates.

There are boiler steam turbine power plant, gas turbine (batch recovery boiler) steam turbine combined power generation plant, and steam generator (IGCC: Integrated coal Gasification Combined), which generate steam (water vapor) in the water supply system circulating the boiler water. Cycle) is a facility that holds a large amount of steam generation system. The coal gasification combined cycle power plant is equipped with a coal gasification furnace, a gas cooler, a gas turbine facility, an arrangement recovery boiler, a steam turbine facility and a generator. In coal gasification, the pulverized coal is gasified to produce a flammable product gas. The gas cooler cools the product gas. Gas turbine installations generate high temperature and high pressure combustion gases by burning the cooled product gas and generate rotational power. The batch recovery boiler recovers thermal energy from the exhaust gas of the gas turbine plant and produces high pressure steam. Steam turbine plants use steam to generate rotational power. The generator converts the rotational power generated by the gas turbine plant and the steam turbine plant into electricity.

The gas cooler and the batch recovery boiler are equipped with a water supply system in which the boiler water circulates. By the boiler water circulating in the feedwater system, the gas cooler cools the product gas produced by the coal gasification furnace, and the batch recovery boiler cools the exhaust gas exhausted from the gas turbine installation. In addition, the gas cooler and the arrangement recovery boiler circulate the water supply system to heat the boiler water and produce the steam supplied to the steam turbine installation.

On the other hand, when the operation of the coal gasification combined cycle power plant is stopped due to periodical inspection, the period during which the equipment is being stored is long, and the piping of the water supply system needs to be replaced, the boiler water should be discharged to cope. However, when storing boiler water without discharging it for quick restart, it is necessary to prevent corrosion of metallic construction materials such as piping inside the water supply system.

Patent Document 1: Japanese Patent Application Laid-Open No. 2004-323954 Patent Document 2: Japanese Patent Application Laid-Open No. 2003-39084 Patent Document 3: JP-A-1992-83592

In the period during which the operation of the power generation facility is stopped and the boiler water is not discharged for quickly restarting while the equipment is being stored, the water supply system is filled with the storage water containing hydrazine, so that it is possible to reduce the corrosion inside the pipe. However, it is known that hydrazine adversely affects health, so careful handling is required (see Patent Documents 1, 2, and 3). It has become necessary to facilitate the corrosion of the metal member of the water supply system and to reduce it for a longer period of time.

Disclosure of Invention Technical Problem [8] The present invention provides a boiler operation method and a boiler which can easily reduce corrosion of a water supply system through which boiler water flows.

The boiler operating method according to the first aspect of the present invention is implemented using the boiler feedwater system part. The boiler includes a water supply system through which heated boiler water flows and an ammonia addition facility for adding ammonia for pH adjustment to the boiler water. The boiler operation method according to the present invention includes: measuring the pH of the boiler water; flowing the boiler water to the water supply system so that the boiler water is heated when the pH is in the operating pH range Controlling the ammonia addition facility so that ammonia is added to the boiler water until the pH is included in the storage pH range when the boiler is stopped; when the pH is in the storage pH range And stopping the flow of the boiler water to the water supply system. At this time, the arbitrary pH included in the storage pH range is equal to or greater than the arbitrary pH included in the operating pH range.

According to such a boiler operating method, boiler water contained in the pH range for storage is filled in the water supply system, so that compared with the boiler water in which the pH is in the operational pH range is filled in the water supply system, It is possible to reduce the corrosion of the water supply system during the storage of the equipment in which the operation of the power generation facility is stopped over a longer period of time. In addition, ammonia is generally easier to handle than hydrazine. Therefore, this boiler operating method can more easily prevent corrosion of the water supply system as compared with filling the water supply system with storage boiler water containing hydrazine.

The boiler operation method according to the first aspect may be such that after the boiler water stops flowing into the water supply system, the boiler water is heated when the pH is included in the operating pH range during the restart operation of the boiler And further causing the boiler water to flow to the water supply system.

According to this boiler operating method, the pH of the storage boiler water is included in the operating pH range, so that it is possible to restart the boiler more easily in a short time by using the storage boiler water as the boiler for operation as it is.

The boiler operation method according to the first aspect of the present invention refers to a table in which a plurality of storage periods correspond to a plurality of storage pH ranges, And further deriving a pH range for use from the above-mentioned several storage pH ranges. At this time, the lower limit of the first storage pH range corresponding to the first period in the plurality of storage pH ranges is the second storage pH corresponding to the second period shorter than the first period in the several storage pH ranges Is greater than the lower limit of the range.

According to this boiler operating method, it is possible to add an appropriate amount of ammonia to the boiler water, and it is possible to more appropriately reduce the corrosion of the water supply system during storage of the equipment.

The boiler according to the second aspect of the present invention includes a water supply system through which heated boiler water flows, an ammonia addition facility for adding ammonia to the boiler water, a pH measurement device for measuring the pH of the boiler water, and an ammonia addition facility And a control device. Wherein the control device controls the ammonia addition facility so that the pH is in the operating pH range when the boiler water flows through the feed water system so that the boiler water is heated during operation of the boiler, And a storage control circuit for controlling the ammonia addition facility so that the pH is included in the storage pH range before the boiler water stops flowing through the water supply system at the time of stop. At this time, the arbitrary pH included in the storage pH range is equal to or greater than the arbitrary pH included in the operating pH range.

As such boilers are filled with boiler water whose pH is in the storage pH range, the boiler water whose pH is in the operational pH range is filled in the water supply system, It is possible to reduce corrosion. In addition, ammonia is generally easier to handle than hydrazine. Therefore, such a boiler can more easily suppress the corrosion of the water supply system during storage of the equipment, as compared with filling the water supply system with storage boiler water containing hydrazine.

The gas cooler according to the third aspect of the present invention includes a flow channel through which a product gas generated by gasifying the carbon-containing solid fuel with an oxidizing agent and a flow channel (a water circulating system of the boiler) through which water flows. At this time, the water supply system uses the heat of the generated gas to heat the boiler water.

Such a gas cooler can more easily suppress the corrosion of the water supply system during the storage of the equipment when the power generation facility is stopped.

The arrangement recovery boiler according to the fourth aspect of the present invention includes a flow passage through which exhaust gas exhausted from a gas turbine flows and a flow passage through which water flows (a boiler water circulation system), and the water supply system uses heat of the exhaust gas Thereby heating the boiler water.

Such an arrangement recovery boiler can more easily prevent the water supply system from corroding during storage of the equipment at the time of stopping the power generation facility.

The coal gasification combined cycle power plant according to the fifth aspect of the present invention is a coal gasification combined cycle power generation facility according to the present invention comprises a boiler for producing a product gas by gasifying an exhaust gas boiler and a carbon containing solid fuel according to the present invention, And a steam turbine for generating power by using steam. At this time, the steam is generated by heating the boiler water using the heat of the generated gas and the heat of the exhaust gas.

Such a coal gasification combined cycle power generation facility can more easily suppress the corrosion of the water supply system during storage of the equipment when the power generation facility is stopped.

The boiler operation method and the boiler according to the present invention can easily reduce the corrosion of the water supply system during the storage of the equipment by charging the boiler water having a pH higher than the pH of the boiler water circulating during operation into the water supply system.

1 is a schematic configuration diagram showing a coal gasification combined cycle power plant.
2 is a schematic diagram showing a boiler water circulation system.
3 is a block diagram showing a control device.
4 is a flow chart showing a boiler storage method of a comparative example.
5 is a graph showing the relationship between pH and corrosion.

Embodiments of the boiler according to the present invention will be described below with reference to the drawings. The water supply system portion of the boiler is used in the coal gasification combined cycle power plant 10 as shown in FIG. The coal gasification combined cycle power plant 10 includes a gasification furnace 1, a gas cooler 2, a gas turbine 3, an arrangement recovery boiler 5, a steam turbine 6, a generator 7 and a condenser 8 Respectively. The gasification furnace 1 generates pulverized coal, which is obtained by crushing coal as a carbon-containing solid fuel supplied from an external facility, and a high temperature production gas having flammability from air (or oxygen) as an oxidizing agent. The gas cooler (2) generates a product gas after cooling from the product gas at a high temperature produced by the gasification furnace (1). By heat exchange to cool this hot product gas, the gas cooler 2 produces high temperature, high pressure steam from the boiler water produced by the condenser 8.

The gas turbine (3) uses the after-cooling gas produced by the gas cooler (2) to generate rotational power and exhaust hot exhaust gas. The batch recovery boiler 5 generates high-temperature and high-pressure steam from the boiler water produced by the condenser 8 by heat exchange for cooling the hot exhaust gas exhausted from the gas turbine 3. The steam turbine (6) uses the steam produced by the gas cooler (2) and the batch recovery boiler (5) to generate rotational power and exhaust steam. The generator (7) generates power using the rotational power generated by the gas turbine (3) and the rotational power generated by the steam turbine (6). The condenser 8 generates water from the exhaust steam exhausted by the steam turbine 6 to produce boiler water.

Fig. 2 shows a water supply (circulation) system part of the gas cooler 2. The gas cooler 2 is provided with a water supply (circulation) system 11, an ammonia addition facility 12, a pH measurement device 14 and a control device 15 and has a product gas flow path a. The product gas flow path (a) flows through the product gas produced by the gasification furnace 1. The water supply system 11 includes a steam drum 16, a plurality of rain water pipes 17, a header 18 and a plurality of heat pipes 19. The steam drum 16 is formed from a steel-based material (hereinafter, referred to as steel) and is formed in a vessel. The steam drum 16 is connected from the condenser 8 via a pipeline 30 so that the boiler water produced by the condenser 8 is supplied to the inside of the steam drum 16. [ The steam drum 16 is connected to the steam turbine 6 via a duct 31 so that the steam generated inside the steam drum 16 is supplied to the steam turbine 6. [ The steam drum 16 is also connected to several precipitation pipes 17 so that the boiler water stored in the steam drum 16 is supplied to the plurality of the precipitation pipes 17.

The plurality of rain water pipes 17 are each formed of steel and form a flow path through which the boiler water supplied from the steam drum 16 flows. A plurality of precipitation pipes 17 are connected to the header 18 so that the boiler water is supplied to the header 18, respectively. The header 18 is formed of steel and is formed in a header to which boiler water supplied from a plurality of the precipitation pipes 17 is joined. The header 18 is also connected to the plurality of heat transfer tubes 19 so that the boiler water is supplied to the plurality of heat transfer tubes 19. [

The plurality of heat transfer tubes 19 are formed of steel and form a flow path through which the boiler water supplied from the header 18 flows. The plurality of heat transfer tubes (19) are arranged in the product gas flow passage (a) so as to be heated by the heat of the product gas generated by the gasification furnace (1). The plurality of heat transfer tubes 19 are also connected to the steam drum 16 so that the boiler water supplied from the header 18 is supplied to the steam drum 16.

The ammonia addition unit 12 is electrically connected to the control unit 15 so as to transmit information, and stores the ammonia solution. The ammonia addition unit 12 is controlled by the control unit 15 to supply the ammonia solution to the conduit 30 so that the ammonia solution is added to the boiler water supplied from the condenser 8 to the steam drum 16. [

The pH measuring device 14 is electrically connected to the controller 15 so that information can be transmitted. The pH measuring device 14 is controlled by the control device 15 to measure the pH of the boiler water stored in the steam drum 16 every predetermined time or continuously.

The control device 15 is a computer, which includes a CPU, a storage device, a memory drive, a communication device, and an interface (not shown).

The interface outputs information generated by an external device connected to the control device 15 to the CPU, and outputs the information generated by the CPU to the external device. The external device includes the ammonia addition unit 12 and the pH measurement unit 14.

The computer program installed in the control device 15 is formed from a plurality of computer programs for realizing a plurality of functions in the control device 15 as shown in Fig. The plurality of functions include a normal control circuit 21 and a storage control circuit 22.

The pH measuring device 14 measures the pH of the boiler water which is stored in at least one steam drum 16 during operation of the gasifier 1 and the gas cooler 2. The normal control circuit 21 previously records the operation pH range in the storage device. The set value of the operating pH range is, for example, 9.7. The control circuit 21 also controls the ammonia addition unit 12 so that the pH of the boiler water stored in the steam drum 16 falls within the operating pH range. In other words, the normal control circuit 21 controls the ammonia addition facility 12 so that the ammonia solution is supplied to the channel 30 when the pH of the boiler water is lower than the set value of the operating pH range. The normal control circuit 21 controls the ammonia addition unit 12 so that the ammonia solution is not supplied to the channel 30 when the pH of the boiler water is equal to or larger than the set value of the operating pH range.

The storage control circuit 22 previously records the storage pH range in the storage device. The lower limit of the storage pH range is equal to or larger than the set value of the operating pH range, for example, 9.7. The storage control circuit 22 also controls the ammonia addition facility 12 so that the pH of the boiler water stored in the steam drum 16 falls within the storage pH range. In other words, the storage control circuit 22 controls the ammonia addition facility 12 so that the ammonia solution is supplied to the channel 30 when the pH of the boiler water stored in the steam drum 16 is lower than the lower limit of the storage pH range do. The storage control circuit 22 controls the ammonia addition unit 12 so that the ammonia solution is supplied to the channel 30 when the pH of the boiler water stored in the steam drum 16 is larger than the lower limit of the storage pH range.

The batch recovery boiler 5 has a water supply system (not shown). The water supply system is formed similarly to the water supply system 11, that is, it has a steam drum, several rain water pipes, a header, and several heat pipes. The steam drum is formed of steel and is formed in a container. The steam drum is connected to the conduit (30) and connected to the conduit (31). The steam drum is also connected to several precipitation pipes so that boiler water stored in the steam drum is supplied to several precipitation pipes.

The plurality of water pipes are each formed of steel and form a flow path for the boiler water supplied from the steam drum. Several precipitation pipes are connected to the header so that boiler water is supplied to the header, respectively. The header is formed of steel and is formed in a container for storing boiler water supplied from several precipitation pipes. The header is also connected to the plurality of heat transfer tubes so that the boiler water is supplied to the plurality of heat transfer tubes.

The plurality of heat transfer tubes are formed of steel and form a flow path for the boiler water supplied from the header. The plurality of heat transfer tubes are arranged in a flow path through which the exhaust gas flows so as to be heated by the heat of the exhaust gas exhausted from the gas turbine (3). The plurality of heat transfer tubes are also connected to the steam drum so that the boiler water supplied from the header is supplied to the steam drum.

An embodiment of the boiler operating method according to the present invention is implemented using the coal gasification combined cycle power plant (10), and includes a normal operation and a storage operation and a restart operation.

In normal operation, in the gasification furnace 1, air (or oxygen) supplied from an external facility is used to crush and burn coal as a carbon-containing solid fuel supplied from an external facility, thereby producing a high- . The gas cooler 2 uses the boiler water produced by the condenser 8 to generate the generated gas after cooling by heat exchange so as to cool the hot generated gas produced by the gasification furnace 1. At this time, the gas cooler 2 generates heat of high temperature and high pressure by heat-exchanging heat of the boiler water to heat the boiler water by using the heat of the generated product gas of high temperature generated by the gasification furnace 1.

The gas turbine (3) burns the produced gas after cooling generated by the gas cooler (2), thereby producing exhaust gas of high temperature and high pressure. The gas turbine 3 also generates rotational power by using the kinetic energy of the exhaust gas, and exhausts the exhaust gas. The batch recovery boiler 5 uses the boiler water produced by the condenser 8 to perform heat exchange so as to cool the hot exhaust gas exhausted from the gas turbine 3 to generate exhaust gas after cooling. At this time, the batch recovery boiler 5 uses the heat of the hot exhaust gas exhausted from the gas turbine 3 to perform heat exchange so as to heat the boiler water produced by the condenser 8, .

The steam turbine 6 generates rotational motion by using the kinetic energy of the high temperature and high pressure steam generated by the gas cooler 2 and the kinetic energy of the steam of high temperature and high pressure generated by the arrangement recovery boiler 5, Exhaust the steam. The generator (7) generates power using the rotational power generated by the gas turbine (3) and the rotational power generated by the steam turbine (6). The condenser 8 generates water by performing heat exchange so as to cool the exhaust steam exhausted by the steam turbine 6 to make boiler water and arranges the boiler water with the gas cooler 2 via the duct 30 And supplies it to the recovery boiler (5).

At this time, the pH measuring device 14 measures the pH of the boiler water stored in the steam drum 16 of the gas cooler 2. The pH measuring device 14 transmits the measured pH to the control device 15. The control device 15 controls the ammonia addition unit 12 to control the ammonia addition unit 12 from the condenser 8 to the steam drum (not shown) by controlling the ammonia addition unit 12 when the set value of the operating pH range is equal to the measured pH, 16) to stop the addition of the ammonia solution to the boiler water. The control device 15 controls the ammonia addition device 12 when the measured pH value is smaller than the set value of the operation pH range set in advance so that ammonia is added to the boiler water supplied from the condenser 8 to the steam drum 16, Add the solution.

The gas cooler 2 circulates the boiler water supplied from the condenser 8 through the pipeline 30 to the water supply system 11 to generate steam from the boiler water. In other words, several precipitation pipes 17 supply boiler water to the header 18, which is stored in the steam drum 16. The header 18 joins the boiler water supplied from the plurality of precipitation pipes 17. The plurality of heat transfer tubes 19 perform heat exchange so as to heat the boiler water being joined at the heating tube header 18 by using the heat of the generated product gas of high temperature generated by the gasification furnace 1, To the steam drum (16). The steam drum 16 stores the boiler water supplied from the condenser 8 and the boiler water heated by the plurality of heat transfer tubes 19 via the pipeline 30. The steam drum 16 also separates the stored and heated boiler water, and supplies the vapor-liquid separated steam to the steam turbine 6. [

The storage operation is performed immediately before the coal gasification combined cycle power plant 10 stops due to periodic maintenance and inspection. The control device 15 measures the pH of the boiler water stored in the steam drum 16 by the pH measuring device 14 immediately before the coal gasification combined cycle power generation facility 10 stops. The controller 15 controls the ammonia addition unit 12 to supply the ammonia solution to the channel 30 when the measured pH is less than the lower limit of the storage pH range. The control device 15 stops the supply of the ammonia solution to the channel 30 by controlling the ammonia addition facility 12 when the measured pH is equal to or lower than the lower limit of the storage pH range.

The coal gasification combined cycle power generation facility 10 stops operation by confirming that the measured pH is equal to or lower than the lower limit of the storage pH range. In the water supply system 11, the operation of the coal gasification combined cycle power generation facility 10 is stopped, and the circulation of the boiler water is stopped. The water supply system (11) further pressurizes and injects nitrogen after the circulation of the boiler water is stopped, thereby exhausting oxygen from the space filled with the gas in the water supply system (11), and the pressurized nitrogen is charged into the space.

Fig. 5 is a graph showing the relationship between pH and corrosion. According to the results of the test in which the test specimens were immersed in an ammonia solution at different pH in an oxygen saturation (25 ° C, 8 mg / l) in a sealed container at room temperature, the presence or absence of corrosion was judged from the surface properties, . When steel is immersed in an ammonia solution, the higher the pH of the ammonia solution is, the lower the rate of corrosion and the corrosion of the steel can be suppressed for a longer period of time. Therefore, according to the storage operation, the water supply system 11 is filled with the boiler water having the pH included in the storage pH range during storage of the stationary equipment of the coal gasification combined cycle power plant 10, Corrosion can be further reduced as compared with the case where the boiler water having the pH included therein is filled. As a result, according to such storage operation, the water supply system 11 can be stored so as not to corrode during storage of stationary equipment of the coal gasification combined cycle power plant 10.

The restart operation is performed after the coal gasification combined cycle power plant 10 has been stopped for a predetermined period after the storage operation is executed. In the re-start operation, the coal gasification combined cycle power plant 10 is different from that at the start of the restart operation after storing the storage water containing hydrazine during the storage of the conventional equipment. The boiler water is extracted from the water supply system 11, The operation is resumed without supplying the boiler water satisfying the water quality of the city, and the normal operation is executed.

According to this restart operation, the coal gasification combined cycle power generation facility 10 does not replace the boiler water whose pH is in the storage pH range with the boiler water whose pH is within the operation pH range, thereby shortening the time required for restarting It is possible to restart the engine in a shorter time than the conventional restart operation.

The comparative example of the boiler operating method is an embodiment of the conventional apparatus storing method and is executed using the coal gasification combined cycle power generation facility 10 in the same manner as the boiler operating method according to the described embodiment, Is replaced with another storage operation, and the restart operation according to the described embodiment is replaced with another restart operation.

In the storage operation, after the coal gasification combined cycle power plant 10 is stopped, boiler water is extracted from the water supply system 11 as shown in Fig. 4 (step S1). The water supply system (11) is filled with the storage water after the boiler water is extracted. Storage water contains 50 mg / L of hydrazine. After the storage water is filled in the water supply system 11, nitrogen is pressurized so that air containing oxygen is exhausted from the space filled with the gas in the water supply system 11, and the pressurized nitrogen is charged into the space S2).

According to such storage operation, the water supply system 11 is filled with the storage water containing 50 mg / L of hydrazine during the stoppage of the coal gasification combined cycle power plant 10, so that the water supply system 11 is constructed It is possible to suppress the corrosion of the steel.

In the restart operation, reservoir water containing hydrazine having a higher concentration than that of hydrazine suitable for normal operation is extracted from the water supply system 11 before restarting the coal gasification combined cycle power generation facility 10 (step S3). The boiler water is charged into the water supply system 11 after the storage water is extracted (step S4). Boiler water is formed from water that does not contain hydrazine. The coal gasification combined cycle power generation facility 10 resumes operation after the boiler water is charged into the water supply system 11 and normal operation is performed.

According to such a restart operation according to the conventional embodiment, the coal gasification combined cycle power plant 10 can appropriately operate the boiler water not containing hydrazine by circulating the water supply system 11 in normal operation.

On the other hand, since ammonia is generally available in comparison with hydrazine, it can be treated more easily.

In addition, the boiler water is not extracted from the water supply system 11 before the water supply system 11 is stored, that is, the ammonia solution is injected and stored at a pH The boiler is restarted without extracting the boiler water of the boiler water, so that the boiler water is not discarded in a shorter period of time than in the restart operation after the equipment is stored in the comparative example. The restart operation according to the embodiment does not extract the boiler water charged in the water supply system 11 at the time of storing the equipment so as to stop the coal gasification combined cycle power plant 10 to start storing the equipment, It is possible to reduce the process of filling the water supply system 11 with the storage water containing hydrazine after the boiler water has been extracted from the water supply system 11 and to extract the storage water containing hydrazine from the water supply system 11 for re- It is possible to reduce the process in which the boiler water is charged. It can be executed in a shorter time as compared with the restart operation of the comparative example. Therefore, according to the boiler operating method according to the embodiment, the coal gasification combined cycle power plant 10 can be stopped in a shorter time and restarted in a shorter time than the boiler operating method of the comparative example.

Further, the operation performed by the control device 15 can be executed by the user. In other words, the user measures the pH of boiler water stored in the steam drum 16 of the gas cooler 2 by controlling the pH measuring device 14. By operating the ammonia addition unit 12, the ammonia solution may be added to the channel 30 and the addition of the ammonia solution may be stopped. In this case as well, the coal gasification combined cycle power generation facility 10 can be more easily prevented from corroding in the same manner as the boiler operating method according to the embodiment, and can be stopped in a shorter time, It is possible to restart. In other words, since the gas cooler 2, the batch recovery boiler is provided with the boiler, it is possible to achieve the above-mentioned effect. The boiler includes a water supply system through which heated boiler water flows, an ammonia addition facility for adding ammonia to the boiler water, and a pH measurement device for measuring the pH of the boiler water.

In another embodiment of the boiler according to the present invention, the storage control circuit 22 according to the embodiment is replaced by another storage control circuit. The storage control circuit previously records several storage pH ranges corresponding to several storage periods in the storage device. Several storage pH ranges are equal to or greater than the setpoints for the operating pH range, respectively. For example, according to the test results shown in Fig. 5, the lower limit of the storage pH range corresponding to the period within 24 hours is 9.5. And the lower limit of the storage pH range corresponding to the period within 72 hours is 9.7. And the lower limit of the storage pH range corresponding to the period of 4 days to 7 days is 9.8. The lower limit of the storage pH range corresponding to the period of 7 days to 14 days is 9.9. And the lower limit of the storage pH range corresponding to the period of 15 to 30 days is 10. As the storage period becomes longer, the lower limit of the corresponding storage pH range becomes larger.

Further, for example, in an environment of high temperature and strong alkaline (pH 11 or more), there is a possibility that even steel which is usually resistant to alkali may be alkali-eroded. Therefore, the upper limit of pH for storage is preferably less than pH 11. However, it is not limited thereto.

The storage operation section calculates the storage pH range corresponding to the storage period from a plurality of storage pH ranges when the storage period is input from the user to the control device 15. [ The storage operation part controls the pH measuring device 14 so that the pH of the boiler water stored in the steam drum 16 is measured. And the storage control circuit controls the ammonia addition unit 12 so that the pH of the boiler water stored in the steam drum 16 falls within the storage pH range. Further, the storage pH range corresponding to the storage period may be calculated, and the ammonia addition facility 12 may be operated not only by controlling the ammonia addition facility 12, but also by manual operation.

The coal gasification combined cycle power plant having such a storage control circuit can be more easily suppressed from corroding the feed water system 11 in the same manner as the coal gasification combined cycle power plant 10 according to the embodiment It is possible to stop in a shorter time, and it is possible to restart in a shorter time.

Fig. 5 shows the relationship between the pH of the storage water and corrosion. The relationship shows the pH of the storage water in which the steel material is immersed, and shows the corrosion area with respect to the number of days that the steel material is immersed in the storage water. The corrosion area shows the ratio of the surface area of the area that is corroded by the elapsed days in the surface to the surface area in contact with the stored water. The relationship also indicates that corrosion progresses with time. The relationship also shows that as the pH of the storage water is increased, the time at which the sealing material begins to corrode is delayed. Therefore, the relationship indicates that the larger the pH of the boiler water charged in the water supply system 11 during storage, the more the corrosion can be prevented for a longer period of time.

Therefore, the longer the storage period for stopping the coal gasification combined cycle power generation system having such a storage control circuit, the larger the lower limit of the storage pH range, thereby reducing the amount of ammonia used for storing the water supply system 11 , It is possible to appropriately prevent the water supply system 11 from corroding.

It is also possible that the storage pH range is replaced by another storage pH range in which the lower limit is 9.5. The lower limit of the storage pH range is equal to the set value of the operating pH range or larger than the set value of the operating pH range.

1 gasification furnace
2 gas cooler
3 gas turbine
5 Sequence recovery boiler
6 Steam turbines
10 Coal gasification combined power generation facility
11 water system
12 Ammonia addition plant
14 pH measuring device
15 control device
21 Conventional control circuit
22 Storage control circuit

Claims (8)

A boiler water flow system,
A boiler operating method executed using a boiler having an ammonia addition facility for adding an ammonia solution to the boiler water,
Measuring the pH of the boiler water,
Flowing the boiler water to the water supply system so that the boiler water is heated when the pH is in the operating pH range during operation of the boiler,
Controlling the ammonia addition facility to add an ammonia solution to the boiler water until the pH is included in a storage pH range when the boiler is stopped,
And stopping the flow of the boiler water to the water supply system when the pH is included in the storage pH range,
Wherein the arbitrary pH included in the storage pH range is equal to or greater than the arbitrary pH included in the operating pH range.
The method according to claim 1,
Flowing the boiler water to the water supply system so that the boiler water is heated when the pH is within the operating pH range during the restart operation of the boiler after stopping the flow of the boiler water to the water supply system Further comprising a boiler operating method.
3. The method according to claim 1 or 2,
The storage pH range corresponding to the power generation facility suspension period in which the boiler water is not allowed to flow in the water supply system is referred to as a table for matching several storage periods to several storage pH ranges, Further comprising:
Wherein the lower limit of the first storage pH range corresponding to the first period of the plurality of storage pH ranges is less than the lower limit of the second storage pH range corresponding to the second period shorter than the first period How to operate a boiler larger than the lower limit.
The method of claim 3,
Wherein the lower limit of the first storage pH range and the lower limit of the second storage pH range are in the range of 9.5 to 10.
A boiler water flow system,
An ammonia addition facility for adding an ammonia solution to the boiler water,
A pH measuring device for measuring the pH of the boiler water,
A boiler having a control device,
During operation of the boiler, the control device
A normal control circuit for controlling the ammonia addition device so that the pH is in the operating pH range when the boiler water flows through the feed water system so that the boiler water is heated;
And a storage control circuit for controlling the ammonia addition facility so that the pH is included in the storage pH range before the boiler water stops flowing through the water supply system when the boiler is stopped,
Wherein any pH included in the storage pH range is equal to or greater than any pH included in the operating pH range.
The boiler according to claim 5,
And a flow path through which a product gas generated by gasifying the carbon-containing solid fuel flows,
Wherein the water supply system uses the heat of the generated gas to heat the boiler water.
The boiler according to claim 5,
And a flow path through which the exhaust gas exhausted from the gas turbine flows,
Wherein the water supply system uses the heat of the exhaust gas to heat the boiler water.
The boiler according to claim 5,
A gasification furnace for producing a produced gas by gasifying the carbon-containing solid fuel,
A gas turbine for exhausting the exhaust gas by generating power using the generated gas;
A steam turbine for generating power using steam,
Wherein the steam is generated by heating the boiler water using the heat of the generated gas and the heat of the exhaust gas.

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