JP2015215136A - Boiler control device and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a boiler control device and a control method capable of more appropriately controlling conductivity of boiler water inside a boiler drum.SOLUTION: There is provided a boiler control system comprising: a water level meter; a feed water valve; a blow valve; first through third flow meters; a conductivity meter; and first and second control sections. The water level meter measures a water level inside a drum. The feed water valve regulates a flow rate of feed water. The blow valve regulates a flow rate of blow. The first flow meter measures the flow rate of the feed water. The second flow meter measures a flow rate of steam. The third flow meter measures the flow rate of the blow. The conductivity meter measures conductivity of water inside the drum. The first control section controls the feed water valve such that the water level is constant. The second control section calculates the conductivity after a predetermined period of time has elapsed on the basis of measurement results of the conductivity meter, the second flow meter and the third flow meter and controls the blow valve such that the conductivity is within a setting range in response to calculation results.

Description

  Embodiments described herein relate generally to a boiler control device and a control method for controlling the conductivity of boiler water in a boiler drum so as to fall within a set range.

  There is a boiler control device that controls the amount of boiler water in a boiler drum to be substantially constant by adjusting the flow rate of boiler water to be supplied according to the flow rate of boiler water to be blown and the flow rate of discharged steam. Hereinafter, the flow rate of boiler water to be blown is referred to as “blow water flow rate”, and the flow rate of boiler water to be supplied is referred to as “feed water flow rate”.

  The boiler control device keeps the blow water flow rate substantially constant when the conductivity of boiler water in the boiler drum (hereinafter referred to as “drum conductivity”) is within a set range. Then, when the drum conductivity is out of the set range, the boiler control device controls the drum conductivity to be within the set range by adding or subtracting the blow water flow rate by a certain amount.

  For this reason, when the blow water flow rate that causes the drum conductivity to decrease is larger than the feed water flow rate that corresponds to the steam flow rate that causes the drum conductivity to increase, the drum conductivity deviates to the lower side of the setting range. End up. For example, since the blow water flow rate increases more than maintaining an appropriate drum conductivity, the temperature in the boiler drum decreases, causing energy loss.

  In addition, when the blow water flow rate is small with respect to the feed water flow rate corresponding to the steam flow rate, the drum conductivity is deviated to the higher side of the setting range, which causes scale adhesion. For this reason, in a boiler control apparatus, it is desired to be able to control drum conductivity more appropriately.

JP 2009-30817 A

  Embodiments of the present invention provide a boiler control device and a control method that can more appropriately control the conductivity of boiler water in a boiler drum.

  According to an embodiment of the present invention, a water level meter, a water supply valve, a blow valve, a first flow meter, a second flow meter, a third flow meter, a conductivity meter, a first control unit, A boiler control device provided with a 2nd control part is provided. The water level gauge measures the water level of boiler water stored in the boiler drum. The water supply valve adjusts the flow rate of boiler water supplied to the boiler drum. The blow valve adjusts the flow rate of boiler water blown from the boiler drum. The first flow meter measures the flow rate of boiler water supplied to the boiler drum. The second flow meter measures a flow rate of steam discharged from the boiler drum. The third flow meter measures the flow rate of boiler water blown from the boiler drum. The conductivity meter measures the conductivity of boiler water stored in the boiler drum. The first control unit controls the water supply valve so that the water level is constant based on the measurement result of the water level meter and the measurement result of the first flow meter. The second control unit calculates the conductivity after a predetermined time based on the measurement result of the conductivity meter, the measurement result of the second flow meter, and the measurement result of the third flow meter. The blow valve is controlled so that the conductivity is within a set range according to the calculation result.

  Provided are a boiler control device and a control method that can more appropriately control the conductivity of boiler water in a boiler drum.

It is a block diagram showing typically the boiler system concerning an embodiment. It is a flowchart which represents typically an example of operation | movement of the boiler control apparatus which concerns on embodiment.

Each embodiment will be described below with reference to the drawings.
The drawings are schematic or conceptual, and the relationship between the thickness and width of each part, the size ratio between the parts, and the like are not necessarily the same as actual ones. Further, even when the same part is represented, the dimensions and ratios may be represented differently depending on the drawings.
Note that, in the present specification and each drawing, the same elements as those described above with reference to the previous drawings are denoted by the same reference numerals, and detailed description thereof is omitted as appropriate.

FIG. 1 is a block diagram schematically illustrating a boiler system according to an embodiment.
As shown in FIG. 1, the boiler system 2 includes a boiler drum 4, a water supply tank 5, a water supply pump 6, a blow water tank 8, and a boiler control device 10.

  The boiler drum 4 stores boiler water in an internal space. The boiler water stored in the boiler drum 4 is heated by a heat source (not shown). The boiler drum 4 accommodates boiler water and steam generated by heating. In other words, the boiler drum 4 is a steam drum. The boiler drum 4 may be connected to a water drum through piping or the like, for example. The boiler water may be heated by the heat source using the boiler drum 4, the water drum, or the piping path between the boiler drum 4 and the water drum. The boiler system 2 may further include a heat source, a water drum, and the like.

  The water supply tank 5 is connected to the boiler drum 4 via piping or the like. The water supply tank 5 stores boiler water supplied to the boiler drum 4. As the boiler water, for example, tap water subjected to a predetermined water treatment is used.

  The water supply pump 6 is provided on a piping path between the boiler drum 4 and the water supply tank 5. That is, the water supply pump 6 is connected to the boiler drum 4 and the water supply tank 5 through piping or the like. The feed water pump 6 feeds boiler water stored in the feed water tank 5 to the boiler drum 4. The feed water pump 6 sends boiler water to the boiler drum 4 by, for example, applying pressure in a pipe between the boiler drum 4 and the feed water tank 5.

  The blow water tank 8 is connected to the boiler drum 4 through piping or the like. The blow water tank 8 stores boiler water blown from the boiler drum 4. That is, the blow water tank 8 stores the boiler water discharged from the boiler drum 4.

  The boiler control device 10 includes a water level meter 12, a water supply valve 14, a blow valve 16, a conductivity meter 18, a first flow meter 21, a second flow meter 22, a third flow meter 23, and a first flow meter. A control unit 31 and a second control unit 32 are included.

  The water level gauge 12 is attached to the boiler drum 4. The water level meter 12 measures the water level of boiler water stored in the boiler drum 4. The water level gauge 12 is electrically connected to the first control unit 31. The water level gauge 12 inputs the measurement result of the boiler water level to the first control unit 31.

  The water supply valve 14 is provided on a piping path between the boiler drum 4 and the water supply tank 5. The water supply valve 14 is connected to the boiler drum 4 and the water supply tank 5 via piping. For example, the water supply valve 14 opens and closes a pipe between the boiler drum 4 and the water supply tank 5. Thereby, the water supply valve 14 adjusts the flow rate of the boiler water supplied to the boiler drum 4. In this example, the water supply valve 14 is provided between the boiler drum 4 and the water supply pump 6. For example, the water supply valve 14 may be provided between the water supply tank 5 and the water supply pump 6.

  The blow valve 16 is provided on a piping path between the boiler drum 4 and the blow water tank 8. The blow valve 16 is connected to the boiler drum 4 and the blow water tank 8 through piping. The blow valve 16 opens and closes a pipe between the boiler drum 4 and the blow water tank 8, for example. Thereby, the blow valve 16 adjusts the flow rate of the boiler water blown from the boiler drum 4.

  The conductivity meter 18 measures the conductivity of boiler water stored in the boiler drum 4 (hereinafter referred to as drum conductivity). In other words, the drum conductivity is a resistance value per unit volume of boiler water stored in the boiler drum 4. In other words, it is the amount of impurities contained per unit volume of boiler water stored in the boiler drum 4. In this example, the conductivity meter 18 is provided on a piping path between the boiler drum 4 and the blow water tank 8. The conductivity meter 18 measures the drum conductivity based on, for example, the conductivity of boiler water blown from the boiler drum 4. The conductivity meter 18 is electrically connected to the second control unit 32. The conductivity meter 18 inputs the drum conductivity measurement result to the second control unit 32. The position of the conductivity meter 18 is not limited to the above, and may be any position where the drum conductivity can be measured. For example, the conductivity meter 18 may be provided in the boiler drum 4.

  The first flow meter 21 is provided on a piping path between the boiler drum 4 and the water supply tank 5. The first flow meter 21 measures the flow rate of boiler water supplied to the boiler drum 4 (hereinafter referred to as a feed water flow rate). The first flow meter 21 is electrically connected to the first control unit 31. The first flow meter 21 inputs the measurement result of the feed water flow rate to the first control unit 31. In this example, the first flow meter 21 is provided between the boiler drum 4 and the water supply valve 14. The position of the first flow meter 21 is not limited to this, and may be an arbitrary position on the piping path between the boiler drum 4 and the water supply tank 5.

  The 2nd flow meter 22 is provided on the path | route of the piping which supplies the vapor | steam discharge | released from the boiler drum 4 to an external apparatus etc. Thereby, the second flow meter 22 measures the flow rate of steam discharged from the boiler drum 4 (hereinafter referred to as the steam flow rate). The second flow meter 22 is electrically connected to the second control unit 32. The second flow meter 22 inputs the measurement result of the steam flow rate to the second control unit 32.

  Further, a pressure gauge 25 and a thermometer 26 are further provided on the steam piping path. The pressure gauge 25 measures the pressure of the steam discharged from the boiler drum 4. The thermometer 26 measures the pressure of the steam discharged from the boiler drum 4. The pressure gauge 25 and the thermometer 26 are electrically connected to the second control unit 32. Each of the pressure gauge 25 and the thermometer 26 inputs a measurement result to the second control unit 32. The pressure gauge 25 and the thermometer 26 are provided as necessary and can be omitted.

  The third flow meter 23 is provided on a piping path between the boiler drum 4 and the blow water tank 8. The third flow meter 23 measures the flow rate of boiler water blown from the boiler drum 4 (hereinafter referred to as blow water flow rate). The third flow meter 23 is electrically connected to the second control unit 32. The third flow meter 23 inputs the measurement result of the blow water flow rate to the second control unit 32. In this example, the third flow meter 23 is provided between the blow valve 16 and the blow water tank 8. The position of the third flow meter 23 is not limited to this, and may be an arbitrary position on the piping path between the boiler drum 4 and the blow water tank 8.

  The first control unit 31 includes a level calculation unit 31a and a flow rate calculation unit 31b. The level calculation unit 31a calculates the correction amount of the feed water flow rate based on the water level measured by the water level gauge 12. The level calculation unit 31a calculates a correction amount of the feed water flow rate for setting the boiler water level in the boiler drum 4 to a predetermined water level. The level calculator 31a calculates the correction amount by, for example, PI calculation.

  The flow rate calculation unit 31b calculates the operation amount of the water supply valve 14 according to the calculation result of the level calculation unit 31a based on the calculation result of the level calculation unit 31a and the measurement result of the first flow meter 21. The flow rate calculation unit 31b calculates the operation amount of the water supply valve 14 by, for example, PI calculation.

  The first control unit 31 controls the water supply valve 14 according to the operation amount calculated by the flow rate calculation unit 31b. Thus, the 1st control part 31 controls the feed valve 14 so that the water level of the boiler water in the boiler drum 4 may become fixed based on the measurement result of the water level meter 12, and the measurement result of the 1st flow meter 21. To do. In other words, the first control unit 31 controls the feed water flow rate so that the water level is constant.

  A predetermined amount of steam is always released from the boiler drum 4. A predetermined amount of boiler water is always blown from the boiler drum 4. The first control unit 31 controls the water supply valve 14 so that the steam flow rate, the blow water flow rate, and the feed water flow rate are substantially constant. Note that the blow may be temporarily stopped.

  Based on the measurement result of the conductivity meter 18, the measurement result of the second flow meter 22, and the measurement result of the third flow meter 23, the second control unit 32 calculates the drum conductivity after a predetermined time has elapsed. The blow valve 16 is controlled so that the drum conductivity falls within the set range according to the calculation result.

  For example, the second control unit 32 calculates the increase amount of the drum conductivity after a predetermined time due to the release of the vapor, based on the measurement result of the second flow meter 22. Based on the measurement result of the conductivity meter 18 and the measurement result of the third flow meter 23, the second control unit 32 calculates a decrease amount of the drum conductivity after a predetermined time has elapsed due to blowing. The second control unit 32 calculates the drum conductivity after a predetermined time has elapsed from the calculated increase amount and decrease amount. And the 2nd control part 32 determines a blow water flow volume based on the calculation result of the drum electrical conductivity after predetermined time, and controls the blow valve 16 according to the determined blow water flow volume.

  The second control unit 32 includes a flow rate calculation unit 32a. The flow rate calculation unit 32a calculates the operation amount of the blow valve 16 according to the determined calculation result of the blow water flow rate based on the determined blow water flow rate and the measurement result of the third flow meter 23. The flow rate calculation unit 32a calculates the operation amount of the blow valve 16 by, for example, PI calculation. The second control unit 32 controls the blow valve 16 according to the operation amount calculated by the flow rate calculation unit 32a. Thus, the second control unit 32 keeps the drum conductivity within the set range.

  Here, T is the predetermined time. The amount of boiler water stored in the boiler drum 4 is DL. Let the blow water flow rate be BL. The flow rate of boiler water supplied with the release of steam is assumed to be JL. The drum conductivity measured by the conductivity meter 18 is Ud0. The conductivity of boiler water to be supplied is Uk. The drum conductivity after a predetermined time has elapsed is defined as Udx.

  The water amount DL is controlled to be substantially constant by the first control unit 31 as described above. Accordingly, the water amount DL is stored in the second control unit 32 as a constant value. The water amount DL may be calculated in real time by the second control unit 32 based on the measurement result of the water level gauge 12, for example.

  The conductivity Uk of boiler water to be supplied is measured in advance and stored in the second control unit 32 as a constant value. For example, another conductivity meter may be provided on the piping path between the boiler drum 4 and the water supply tank 5, and the conductivity Uk may be measured in real time and input to the second control unit 32.

  The flow rate JL of boiler water supplied with the release of steam is calculated by the second control unit 32 based on the measurement results of the second flow meter 22, the pressure gauge 25, and the thermometer 26, for example. For example, the second control unit 32 may calculate the flow rate JL from only the measurement result of the second flow meter 22. However, as described above, the flow rate JL is calculated from the measurement results of the second flow meter 22, the pressure gauge 25, and the thermometer 26. Thereby, the flow rate JL can be calculated more accurately.

  The total amount of boiler water supplied with the release of steam from the present time until the elapse of the predetermined time T is represented by “JL × T”.

  From the conductivity Uk, the increase in conductance after a predetermined time T has elapsed due to the release of the vapor is represented by “JL × T × Uk”. In other words, “JL × T × Uk” is the amount of increase in impurities (substance related to conductivity) in boiler water after a predetermined time T has elapsed due to the release of steam.

From the amount of water DL, the amount of increase in conductivity after elapse of a predetermined time T accompanying the release of steam is
It is represented by “JL × T × Uk / DL”.

  Similarly, the total amount of boiler water supplied with blow from the present time until the elapse of the predetermined time T is represented by “BL × T”.

The amount of increase in conductance after elapse of a predetermined time T associated with blow is
It is represented by “BL × T × Uk”.

On the other hand, since the boiler water having the drum conductivity Ud0 is discharged, the amount of decrease in conductance after the lapse of the predetermined time T accompanying the blow is
It is represented by “BL × T × Ud0”. However, the change in drum conductivity Ud0 during discharge is ignored as being small.

The drum conductivity Ud0 is larger than the conductivity Uk of the water supply. Therefore, the amount of decrease in conductance after a lapse of a predetermined time T accompanying blow is
It is represented by “BL × T × (Ud0−Uk)”.

As a result, the amount of decrease in conductivity after a predetermined time T has elapsed due to blow is
It is represented by “BL × T × (Ud0−Uk) / DL”.

From the above, the drum conductivity Udx after a predetermined time T has elapsed from the current drum conductivity Ud0 is determined from the current drum conductivity Ud0, the increase amount due to the release of steam, and the decrease amount due to the blow.
Udx = Ud0 + (JL × T × Uk / DL) − (BL × T × (Ud0−Uk) / DL)
It can be calculated by the first equation represented by

Summarizing the above first formula for the blow water flow rate BL,
BL = JL × Uk / (Ud0−Uk) + DL × ((Ud0−Udx) / (Ud0−Uk)) / T
It becomes.

In the case where the drum conductivity Udx is within the set range to be stored, in the above equation, the drum conductivity Udx is considered to be the same as the drum conductivity Ud0.
That is, it is considered that (Ud0−Udx) = 0.

In this case,
BL = (JL × Uk) / (Ud0−Uk)
The blow water flow rate BL is determined by the second equation represented by As a result, the drum conductivity Udx can be kept within the set range.

On the other hand, when the drum conductivity Udx is within the set range to be stored, the drum conductivity Udx is replaced with the target value Uds in the above equation. That is,
BL = JL × Uk / (Ud0−Uk) + DL × ((Ud0−Uds) / (Ud0−Uk)) / T
The blow water flow rate BL is determined by the third equation represented by

  Thereby, the drum conductivity after the predetermined time T has elapsed can be set to the target value Uds. The target value Uds is set within the drum conductivity setting range. For example, the target value Uds is set to a median value between the upper limit and the lower limit of the setting range. The target value Uds may be an arbitrary value between the upper limit and the lower limit of the setting range.

  The second control unit 32 calculates the drum conductivity Udx after the predetermined time T has elapsed, according to the first equation. Then, it is determined whether or not the drum conductivity Udx is within the set range. If it is determined that it is within the set range, the blow water flow rate BL is determined by the above second equation, and the blow valve 16 is controlled in accordance with the determined blow water flow rate. On the other hand, if it is determined that it is not within the set range, the blow water flow rate BL is determined by the above third equation, and the blow valve 16 is controlled in accordance with the determined blow water flow rate.

  Further, the second control unit 32 determines whether or not the drum conductivity Ud0 is within the set range based on the drum conductivity Ud0 measured by the conductivity meter 18. If it is determined that the second control unit 32 is within the set range, the second control unit 32 executes a process of calculating the drum conductivity Udx using the first equation. On the other hand, if it is determined that it is not within the set range, the blow water flow rate BL is determined by the above third equation, and the blow valve 16 is controlled in accordance with the determined blow water flow rate.

  The first control unit 31 and the second control unit 32 are provided in different processors, for example. The first control unit 31 and the second control unit 32 may be provided in one processor. That is, the first control unit 31 and the second control unit 32 may be logical blocks provided in one processor.

FIG. 2 is a flowchart schematically illustrating an example of the operation of the boiler control device according to the embodiment.
As illustrated in FIG. 2, the first control unit 31 of the boiler control device 10 controls the water level of the boiler water in the boiler drum 4 to be substantially constant when the operation is started (step S01). The first control unit 31 controls the water supply valve 14 based on the measurement result of the water level meter 12 and the measurement result of the first flow meter 21 so that the water level of the boiler water in the boiler drum 4 is constant.

  When starting the operation, the second control unit 32 measures the drum conductivity Ud0 (step S02). That is, the second control unit 32 acquires the measurement result of the drum conductivity Ud0 from the conductivity meter 18 in response to the start of the operation.

  The second control unit 32 determines whether or not the acquired drum conductivity Ud0 is within the set range (step S03).

  When it is determined that the drum conductivity Ud0 is within the set range, the second control unit 32 calculates the drum conductivity Udx after a predetermined time has elapsed according to the first equation (step S04).

  After calculating the drum conductivity Udx, the second control unit 32 determines whether the drum conductivity Udx is within the set range (step S05).

  When the second control unit 32 determines that the drum conductivity Udx is within the set range, the second control unit 32 determines the blow water flow rate BL according to the above second formula, and controls the blow valve 16 according to the determined blow water flow rate. (Step S06).

  On the other hand, when the second control unit 32 determines that the drum conductivity Udx is not within the set range, the second control unit 32 determines the blow water flow rate BL according to the above third formula, and the blow valve 16 according to the determined blow water flow rate. Is controlled (step S07).

  Further, when the second control unit 32 determines in step S03 that the drum conductivity Ud0 is not within the set range, the second control unit 32 determines the blow water flow rate BL by the above-described third formula, and according to the determined blow water flow rate. The blow valve 16 is controlled.

  Thus, the boiler control apparatus 10 according to the present embodiment is based on the measurement result of the conductivity meter 18, the measurement result of the second flow meter 22, and the measurement result of the third flow meter 23 for a predetermined time. The drum conductivity Udx after T has elapsed is calculated, and the blow valve 16 is controlled so that the drum conductivity falls within the set range according to the calculation result.

  Thereby, in the boiler control device 10 according to the present embodiment, for example, the boiler water in the boiler drum 4 is compared with a control device that adds or subtracts a certain amount of blow water flow when the drum conductivity is out of the set range. Can be kept within a longer time setting range.

  Therefore, for example, it is possible to suppress the occurrence of scale adhesion due to the drum conductivity deviating to the higher setting range side. For example, it is possible to prevent the blow water flow rate from being increased more than necessary due to the drum conductivity deviating to the lower side of the setting range. For example, it is possible to suppress the occurrence of energy loss due to a decrease in temperature in the boiler drum 4 as the blow water flow rate increases.

  Thus, in the boiler control apparatus 10 which concerns on this embodiment, the electrical conductivity of the boiler water in the boiler drum 4 can be controlled more appropriately.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 2 ... Boiler system, 4 ... Boiler drum, 5 ... Water supply tank, 6 ... Water supply pump, 8 ... Blow water tank, 10 ... Boiler control device, 12 ... Water level meter, 14 ... Water supply valve, 16 ... Blow valve, 18 ... Conductivity Rate meter, 21 ... first flow meter, 22 ... second flow meter, 23 ... third flow meter, 25 ... pressure gauge, 26 ... thermometer, 31 ... first control unit, 32 ... second control unit

Claims (5)

A water level meter for measuring the level of boiler water stored in the boiler drum;
A water supply valve for adjusting a flow rate of boiler water supplied to the boiler drum;
A blow valve for adjusting the flow rate of boiler water blown from the boiler drum;
A first flow meter for measuring a flow rate of boiler water supplied to the boiler drum;
A second flow meter for measuring a flow rate of steam discharged from the boiler drum;
A third flow meter for measuring the flow rate of boiler water blown from the boiler drum;
A conductivity meter for measuring the conductivity of boiler water stored in the boiler drum;
Based on the measurement result of the water level meter and the measurement result of the first flow meter, a first control unit that controls the water supply valve so that the water level becomes constant;
Based on the measurement result of the conductivity meter, the measurement result of the second flow meter, and the measurement result of the third flow meter, the conductivity after a lapse of a predetermined time is calculated, and according to the calculation result A second control unit that controls the blow valve so that the conductivity falls within a set range;
Boiler control device equipped with.   The second control unit calculates the amount of increase in the conductivity after elapse of the predetermined time due to the release of the vapor based on the measurement result of the second flow meter, and the measurement result of the conductivity meter and the Based on the measurement result of the third flow meter, the decrease amount of the conductivity after the predetermined time has elapsed due to blow is calculated, and the conductivity after the predetermined time has elapsed from the increase amount and the decrease amount is calculated. The boiler control device according to claim 1, wherein the boiler control device calculates and determines a flow rate of boiler water to be blown based on a calculation result of the conductivity after the predetermined time has elapsed, and controls the blow valve according to the determined flow rate. The predetermined time is T,
DL is the amount of boiler water stored in the boiler drum,
Let BL be the flow rate of the boiler water to be blown.
The flow rate of boiler water supplied with the release of steam is JL,
The conductivity measured by the conductivity meter is Ud0,
The conductivity of boiler water to be supplied is Uk,
The conductivity after elapse of the predetermined time is Udx,
When the target value of the conductivity set within the setting range is Uds,
The second controller is
Udx = Ud0 + (JL × T × Uk / DL) − (BL × T × (Ud0−Uk) / DL)
When the conductivity Udx is calculated by the first equation expressed by the following equation, and the conductivity Udx is within the set range,
BL = (JL × Uk) / (Ud0−Uk)
When the flow rate of the boiler water to be blown is determined by the second equation expressed by the following equation and the conductivity Udx is not within the set range,
BL = JL × Uk / (Ud0−Uk) + DL × ((Ud0−Uds) / (Ud0−Uk)) / T
The boiler control apparatus of Claim 2 which determines the flow volume of the boiler water to blow by 3rd Formula represented by these.   The boiler control device according to claim 3, wherein the second control unit determines the flow rate of the boiler water to be blown according to the third equation when the conductivity Ud0 is not within the set range. Based on the measurement result of the water level meter that measures the water level of the boiler water stored in the boiler drum and the measurement result of the first flow meter that measures the flow rate of the boiler water supplied to the boiler drum, the water level is A step of controlling a water supply valve for adjusting the flow rate of boiler water supplied to the boiler drum so as to be constant;
From the measurement result of the conductivity meter that measures the conductivity of the boiler water stored in the boiler drum, the measurement result of the second flow meter that measures the flow rate of the steam discharged from the boiler drum, and the boiler drum Based on the measurement result of the third flow meter that measures the flow rate of the boiler water to be blown, the conductivity after a predetermined time has elapsed is calculated, and the conductivity falls within a set range according to the calculation result. A step of controlling a blow valve for adjusting the flow rate of boiler water blown from the boiler drum,
A boiler control method comprising:

Images