JP4937089B2 - Cyclone clogging judgment device and cyclone clogging judgment method - Google Patents

Description

  The present invention relates to a cyclone clogging determination apparatus and a cyclone clogging determination method for determining the clogging state of a cyclone used for pressurized fluidized bed combined power generation.

  Pressurized Fluidized-bed Boiler Combined Cycle (PFBC) burns fine coal in a boiler housed in a pressure vessel and rotates a steam turbine with steam generated by the combustion. Generate electricity. At the same time, the gas turbine is rotationally driven using the exhaust gas from the boiler to generate power. At this time, since the exhaust gas of the boiler contains soot, the exhaust gas is passed through a cyclone and the exhaust gas from the boiler is sent to the gas turbine (see, for example, Patent Document 1). A cyclone is a device that removes soot and dust from exhaust gas by centrifugation. According to such a power plant, since the output from the steam turbine and the output from the gas turbine can be obtained as the plant output, efficient power generation is possible.

By the way, as described above, the cyclone removes soot from the exhaust gas of the boiler, but the cyclone may be clogged with soot and it may be difficult to operate the cyclone. In view of this, the operator has determined whether or not the cyclone is clogged based on the trend of the process value indicating the interval at which dust is discharged from the cyclone.
JP-A-10-249242

  However, if the operator judges clogging of a cyclone based on the trend of process values in pressurized fluidized bed combined power generation, the judgment may vary depending on individual differences due to differences in the experience of the operator, etc., and the judgment of clogging of the cyclone varies. Sometimes.

  An object of the present invention is to provide a cyclone clogging determination device and a cyclone clogging determination method capable of solving the above-described problems and eliminating the difference in the determination of clogging of a cyclone by an operator.

In order to solve the above problems, a first aspect of the present invention, the clogging state of the cyclone the power output is provided to the power plant supplied to the load while the power generation by combustion of coal, Ya cyclone payout spacing of the cyclone A cyclone clogging judgment device for judging from operation data such as cyclone plenum differential pressure and operation data of a gas turbine that generates electricity from exhaust gas generated by coal combustion by removing dust from the exhaust gas, Storage means for storing reference data such as reference values and deviations created based on normal operation data for each species and load, a plurality of input operation data, and the storage corresponding to the operation data The difference between the reference value of the means and the reference value of the means is compared with the deviation, and if the difference from the reference value is outside the deviation, the reference data is determined to be fluctuated. A change determination processing means that, by the change determination processing means, cyclones payout interval of the operating data is extended, and, based on whether the cyclone plenum differential pressure is determined to have risen, clogging of the cyclone A cyclone clogging determination device comprising: a blockage determination processing unit that determines a state.

The invention according to claim 1 is a cyclone clogging determination device, in a power plant that generates power by combustion of coal and supplies power generation output to a load. The determination is made based on the data and the operation data of the gas turbine. In addition, a gas turbine produces electric power with the exhaust gas from which the cyclone removed the dust from the exhaust gas generated by the combustion of coal. In such a cyclone clogging determination device, the storage means stores in advance reference data created based on normal operation data for each coal type and load. The variation determination processing means compares the difference between the plurality of input operation data and the reference value of the reference data of the storage means corresponding to the operation data, and the difference from the reference value is the deviation. If it is outside, it is determined that the reference data has a fluctuation. The blockage determination processing means determines whether the cyclone is clogged based on whether or not the fluctuation determination processing means determines that the cyclone delivery interval of the operation data has been extended and the cyclone plenum differential pressure has increased. To do.

The invention of claim 2 is the clogging determining device for a cyclone according to claim 1, when the cyclone is connected in two stages, the operation data, each of the first-stage cyclone and the second stage cyclones The blockage determination processing means has operation data , wherein the first-stage cyclone payout interval of the operation data is extended, the second-stage cyclone payout interval is shortened, and the first-stage cyclone plenum difference is The clogging state of the first-stage cyclone is determined based on whether or not it is determined that the pressure has increased .

The invention according to claim 3, in the clogging determination apparatus cyclone according to claim 2, wherein the closure determination processing unit is extended cyclone payout interval of the second stage of the operation data, and the second stage cyclones plenum Based on whether or not it is determined that the differential pressure is increasing, the clogging state of the second-stage cyclone is determined.

According to the invention of claim 4 , the clogged state of the cyclone provided in the power plant that generates power by burning coal and supplies the power output to the load, the operation data such as the cyclone discharge interval and the cyclone plenum differential pressure of the cyclone , , A cyclone clogging determination method for determining by the operation data of a gas turbine that generates power from exhaust gas generated by removing dust from the exhaust gas generated by combustion of coal, Reference data such as reference values and deviations created based on the operation data are stored, and the difference between the plurality of input operation data and the reference value of the stored reference data corresponding to the operation data, and the deviation If the difference from the reference value is outside the deviation, it is determined that the reference data is fluctuated and the cyclone payout interval of the operation data is extended. And, based on whether the cyclone plenum differential pressure is determined to have risen, it determines the clogging state of said cyclone, a cyclone clogging determination method characterized by.

According to the inventions of claim 1 and claim 4 , when the load changes and the coal type changes, the operation data changes. Therefore, a reference created based on the input operation data and normal operation data. By comparing the difference from the data reference value and the deviation, it is possible to reliably determine the clogging state of the cyclone, that is, the tendency or clogging of the cyclone. At this time, since the determination by the operator is unnecessary, the difference in the determination of the clogged state of the cyclone due to the individual difference of the operator can be eliminated.

Moreover , even if there is a difference in load or charcoal type and the payout interval changes, the cyclone plenum differential pressure is also used, so the clogged state of the cyclone can be reliably determined.

According to the invention of claim 2 , when the cyclone is connected in two stages, even if there is a difference in load or coal type and the discharge interval changes, the cyclone plenum differential pressure is used together. It is possible to reliably determine the clogging state.

According to the invention of claim 3 , when the cyclone is connected in two stages, the cyclone plenum differential pressure is used together even if there is a difference in load or coal type and the discharge interval changes, so the second stage cyclone It is possible to reliably determine the clogging state.

  Next, a cyclone clogging determination device (hereinafter simply referred to as “determination device”) according to an embodiment of the present invention will be described as an example in which the determination device is used for pressurized fluidized bed combined power generation. A determination apparatus according to this embodiment is shown in FIG. The determination device 1 in FIG. 1 is installed to determine the clogging state of the dust removal device 110 that removes the dust from the exhaust gas discharged from the boiler 102 in the pressure vessel 101. The pressure vessel 101, the boiler 102, and the dust removal device 110 are a part of a power plant using pressurized fluidized bed combined power generation. The boiler 102 is accommodated in the pressure vessel 101, burns fine coal, and sends high-temperature and high-pressure steam to a steam turbine (not shown). This steam turbine (ST) generates electric power by rotational driving with steam.

  On the other hand, the exhaust gas in the pressure vessel 101 is sent to the dust removing device 110. The dust removal device 110 removes the dust from the exhaust gas in the pressure vessel 101 and sends the exhaust gas from which the dust has been removed to a gas turbine (not shown). This gas turbine (GT) generates electric power by rotational driving with exhaust gas.

The dust removing device 110 includes a two-stage connected cyclone, that is, a primary cyclone 111 and a secondary cyclone 112, and ash coolers 113 and 114. The primary cyclone 111 removes dust from the exhaust gas of the boiler 102 by centrifugation. The primary cyclone 111, as shown in FIG. 2, in a substantially cylindrical hopper 111A, a plurality of cyclones 111B is disposed in the cyclone 111B, inflow pipe 111C from the top of the inlet 111A ₁ of the hopper 111A The exhaust gas flows in through. Cyclone 111B generates a centrifugal force, to efflux ash AS collected by separating the dust in the exhaust gas by the centrifugal force from the outlet 111B _1. The ash AS flowing out from the cyclone 111B may fall to the bottom of the hopper 111A, which is from the discharge port 111A ₂ to be paid out in the ash cooler 113 side. On the other hand, the exhaust gas which has been demineralized by cyclone 111B is made from the outlet 111A ₃ of the hopper 111A upper to be sent to the gas turbine side.

  The secondary cyclone 112 removes soot and dust from the exhaust gas of the primary cyclone 111 by centrifugation, sends the exhaust gas from which dust has been removed to the gas turbine, and discharges the ash AS to the ash cooler 114 side. Since secondary cyclone 112 has the same structure as primary cyclone 111, description of secondary cyclone 112 is omitted. In addition, below, the member of FIG. 2 is used also about the secondary cyclone 112. FIG.

  The ash coolers 113 and 114 have a screw feeder (S / F) built in and cooled while feeding the ash AS from the hoppers of the primary cyclone 111 and the secondary cyclone 112 to the next ash treatment apparatus (not shown). send.

  Such a dust removing device 110 sends a large number of operation data such as a primary cyclone payout interval and a secondary cyclone payout interval representing the discharge state of the ash AS from the primary cyclone 111 and the secondary cyclone 112 to the determination device 1.

  1 includes a processing unit 11, a storage unit 12, an interface 13, a display unit 14, an input unit 15, and an output unit 16. The storage unit 12, the interface 13, the display unit 14, the input unit 15, and the output unit 16 are connected to the processing unit 11 via the bus 17. The display unit 14 of the determination device 1 is a display device such as an LCD (Liquid Crystal Display) that displays the processing result of the processing unit 11 under the control of the processing unit 11. The input unit 15 is an input device such as a keyboard and a mouse, and the output unit 16 is a printing device that prints and outputs data under the control of the processing unit 11.

The interface 13 receives operation data from a dust removal device 110 that removes dust from the exhaust gas in the pressure vessel 101, a gas turbine that is rotationally driven by the exhaust gas, and an automatic plant controller (APC) that controls the power plant. . The operation data received by the interface 13 includes
APC output (MW)
Primary / secondary cyclone inlet / outlet differential pressure (kPa)
Primary and secondary cyclone ash output gas temperature (℃)
Primary / secondary cyclone plenum differential pressure (kPa)
Primary / secondary cyclone S / F (screw feeder) high chilled water output temperature (℃)
Primary / secondary cyclone ash S / F (screw feeder) input ash temperature (° C)
Primary / secondary cyclone payout interval (h (hours): m (minutes))
GT (gas turbine) exhaust gas dust concentration (mg / m3N)
There is.

The APC output is a value representing the amount of power generated by the steam turbine and gas turbine of the power plant. The cyclone inlet / outlet differential pressure has two values, a primary cyclone 111 and a secondary cyclone 112, and the cyclone inlet / outlet differential pressure is a difference in pressure between the inlet 111A ₁ (FIG. 2) and the outlet 111A ₃ (FIG. 2). Represents. The cyclone ash output gas temperature has two values, a primary cyclone 111 and a secondary cyclone 112, and the cyclone ash output gas temperature represents the gas temperature at the outlet 111A ₂ (FIG. 2). The cyclone plenum differential pressure has two values, a primary cyclone 111 and a secondary cyclone 112, and the cyclone plenum differential pressure temporarily transfers the plenum, that is, exhaust gas provided in the primary cyclone 111 and the secondary cyclone 112. It represents the difference in pressure between the location where the exhaust gas enters the plenum and the location where the cyclone is connected, in the portion that is stored in and flows to each cyclone 111B.

The cyclone S / F high chilled water output temperature has two values on the primary cyclone 111 side and the secondary cyclone 112 side. The cyclone S / F high chilled water output temperature is installed in the ash cooler 113 and the ash cooler 114. It represents the output temperature of the high-temperature cold water flowing through the screw feeder shaft. There are two values for the cyclone ash S / F input ash temperature, the primary cyclone 111 side and the secondary cyclone 112 side. The cyclone ash S / F input ash temperature is installed in the ash cooler 113 and the ash cooler 114. It represents the temperature of the ash AS at the inlet portion of the screw feeder. The GT exhaust gas dust concentration represents the amount of soot at the outlet of the gas turbine. The cyclone payout interval has two values on the primary cyclone 111 side and the secondary cyclone 112 side, and the cyclone payout interval represents an interval at which the ash AS is discharged from the discharge port 111A ₂ (FIG. 2).

  When the interface 13 receives the above-described values representing the APC output to the GT exhaust gas dust concentration as operation data, the interface 13 sends these values to the processing unit 11.

The storage unit 12 is a storage device having a storage area for storing data under the control of the processing unit 11 and a storage area for storing processing procedures. The storage unit 12 stores a processing procedure for determining clogging of the dust removing device 110 in the storage area as a processing procedure. The storage unit 12 stores a reference value table in a data storage area. The reference value table is used in the clogging determination process by the processing unit 11, and as shown in FIG. 3, the reference value table includes each reference value A of APC output to GT exhaust gas dust concentration as the operation data described above. ₁ , A ₂ , A _{3 to} A _14, and deviations B ₁ , B ₂ , B _{3 to} B ₁₄ that are allowable fluctuation ranges with respect to the reference value are recorded. Each of the reference values A ₁ , A ₂ , A _{3 to} A ₁₄ is a value created based on past normal operation data. Note that the unit of each value is also recorded in the reference value table. Furthermore, since the reference value and deviation differ depending on the type of coal such as umbo coal, and also differ depending on the difference in APC output due to the difference in load, the reference value and deviation are recorded in the reference value table for each type of coal. In addition, a reference value and a deviation are recorded for each APC output.

  Moreover, the memory | storage part 12 has memorize | stored the driving | operation data table shown in FIG. 4 in the memory area which memorize | stores data. The operation data table will be described later.

  The processing unit 11 performs clogging determination processing according to the processing procedure stored in the storage unit 12. That is, when the processing unit 11 receives an instruction input for determining the clogging state of the dust removing device 110 from the input unit 15, the processing unit 11 starts the clogging determination process according to the processing procedure stored in the storage unit 12. The clogging determination process includes two processes. One is a fluctuation determination process, and the other is a blockage determination process. When the clogging determination process is started, the processing unit 11 first performs a fluctuation determination process for determining whether or not fluctuations have occurred in the reference data. Next, based on the result of the fluctuation determination process, the processing unit 11 performs the fluctuation determination process. Blockage determination processing for determining the clogging state of the primary cyclone 111 and the secondary cyclone 112 is performed.

When starting the fluctuation determination process of the clogging determination process, the processing unit 11 controls the display unit 14 to display an input screen for inputting the coal type as shown in FIG. 5 (step S1). When coal type data representing the coal type is received from the input unit 15 after step S1 (step S2), the processing unit 11 waits for input of operation data (step S3). When the operation data is received from the interface 13 in step S3 (step S4), the processing unit 11 records the received operation data as comparison data in the operation data table (step S5). In step S5, the processing unit 11 creates an operation data table using the value of the reference value table corresponding to the coal type received in step S2 and the APC output received in step S4, and stores it in the data storage area of the storage unit 12. Remember. This operation data table is shown in FIG. 4 described above. In the operation data table of FIG. 4, comparison data is recorded together with the reference value and deviation of each operation data. In the operation data table of FIG. 4, the case where the coal type is Wombo coal and the output is A ₁ (MW) is taken as an example, and in the following, the table of FIG. 4 is used as the operation data table.

After step S5, the processing unit 11 determines whether all operation data has been received (step S6). If it is determined in step S6 that all the operation data has been received, the processing unit 11 compares the difference between the comparison data value and the reference data value in the operation data table (FIG. 4) and the deviation (step S7). Note that the processing unit 11 does not compare the deviation for the APC output in step S7. If the difference value is within the deviation in step S7, the processing unit 11 determines that the comparison data has not changed with respect to the reference data (step S8). That is, if the reference data is the value A _k , the comparison data is the value B _k , and the deviation is the value D _k ,
−D _k <B _k −A _k <D _k
The processing unit 11 determines that the comparison data value B _k has not changed. Where the value k is
1 ≦ k ≦ 14
An integer in the range At this time, the processing unit 11 adds a symbol “→” to the operation data table (FIG. 4) to make the determination “◯”.

If the difference value is outside the deviation in step S7, the processing unit 11 determines that the comparison data fluctuates with respect to the reference data (step S9). That is, in the operation data table (FIG. 4),
-D _{k> B k} -A _k or _{B k -A} k> _D k
The processing unit 11 determines that the comparison data value B _k is fluctuating. At this time, if the fluctuation is in an increasing direction, the processing unit 11 adds a symbol “↑” to the operation data table (FIG. 4) to make the determination “x”, and if it is in the decreasing direction, the operation data table (FIG. ) Is added with a sign of “↓” to make the determination “×”.

  When step S8 and step S9 are completed, the processing unit 11 records the determination results of step S8 and step S9 in the operation data table (FIG. 4), updates the operation data table (FIG. 4) (step S10), and determines variation. The process ends.

  On the other hand, if there is no operation data in step S4, or if it is determined in step S6 that all operation data has not been received, the processing unit 11 returns the process to step S3.

  Thus, the processing unit 11 determines whether or not there is a change in the operation data that is the comparison data by the change determination process. Thereafter, the processing unit 11 performs blockage determination processing for the primary cyclone 111 and the secondary cyclone 112. When the processing unit 11 starts the blockage determination process for the primary cyclone 111, as shown in FIG. 6, the processing unit 11 checks the payout interval of the primary cyclone 111 in the operation data table (FIG. 4) (step S21), and this payout interval. Is determined to be longer than the standard data (step S22). If the primary cyclone payout interval has been extended in step S22, the processing unit 11 checks the payout interval of the secondary cyclone 112 in the operation data table (FIG. 4) (step S23), and this payout interval becomes the standard data. It is determined whether or not the time is shorter than the comparison (step S24). If the secondary cyclone dispensing interval is shortened in step S24, the processing unit 11 checks the plenum differential pressure of the primary cyclone 111 in the operation data table (FIG. 4) (step S25), and this differential pressure increases. It is judged whether it is (step S26).

  If the primary cyclone plenum differential pressure has increased in step S26, the processing unit 11 determines that the primary cyclone 111 is prone to clogging (step S27). After step S27, the processing unit 11 creates a clogging message indicating the clogging tendency of the primary cyclone 111 (step S28), controls the display unit 14 to display this clogging message, and controls the output unit 16 This clogging message is output (step S29).

  On the other hand, when the primary cyclone payout interval is not extended at step S22, when the secondary cyclone payout interval is not shortened at step S24, when the primary cyclone plenum differential pressure is not increased at step S26, the processing unit 11 determines that the primary cyclone 111 is normal (step S30). After step S30, the processing unit 11 creates a normal message indicating the normality of the primary cyclone 111 (step S31), controls the display unit 14 to display this normal message, and controls the output unit 16 to control this. A normal message is output (step S32), and the primary cyclone 111 blockage determination process ends.

  When the processing unit 11 starts the blockage determination process of the secondary cyclone 112, as shown in FIG. 7, the processing unit 11 checks the payout interval of the secondary cyclone 112 in the operation data table (FIG. 4) (step S41), and this payout interval. Is determined to be longer than the standard data (step S42). When the secondary cyclone payout interval is extended in step S42, the processing unit 11 checks the plenum differential pressure of the secondary cyclone 112 in the operation data table (FIG. 4) (step S43), and this differential pressure increases. It is determined whether or not (step S44). If the secondary cyclone plenum differential pressure has increased in step S44, the processing unit 11 determines that the secondary cyclone 112 is prone to clogging (step S45). After step S45, the processing unit 11 creates a clogging message indicating the clogging tendency of the secondary cyclone 112 (step S46), controls the display unit 14 to display this clogging message, and controls the output unit 16 This clogging message is output (step S47).

  On the other hand, if the secondary cyclone payout interval is not shortened in step S42, or if the secondary cyclone plenum differential pressure is not increased in step S44, the processing unit 11 determines that the secondary cyclone 112 is normal ( Step S48). After step S48, the processing unit 11 creates a normal message indicating the normality of the secondary cyclone 112 (step S49), controls the display unit 14 to display this normal message, and controls the output unit 16 to control this. A normal message is output (step S50), and the blockage determination process for the secondary cyclone 112 is terminated.

  In this way, the processing unit 11 checks whether or not the primary cyclone 111 and the secondary cyclone 112 have a tendency to be clogged by the blocking determination process, and outputs a message indicating the result of the check. Such blockage determination processing is not limited to FIG. 6 and FIG. 7, for example, the clogging state of the primary cyclone 111 and the secondary cyclone 112 according to the number of “x” indicating that there is a change in the operation data table (FIG. 4). May be examined. Further, the clogged state of the primary cyclone 111 and the secondary cyclone 112 may be checked with reference to the determination result of the operation data table (FIG. 4) and the past fluctuation state.

  Next, the operation of this embodiment will be described. The boiler 102 of the pressure vessel 101 sends steam generated by the combustion of the refined coal to the steam turbine, and the steam turbine generates power with this steam. The exhaust gas from the boiler 102 is sent to the soot removal device 110, soot is removed by the soot removal device 110 having a two-stage configuration of the primary cyclone 111 and the secondary cyclone 112, and the exhaust gas from which the soot has been removed is sent to the gas turbine. The gas turbine generates power with this exhaust gas.

  In such a state, the plant automatic control device (APC) sends the APC output, which is the amount of power generated by the steam turbine and the gas turbine, to the determination device 1 as operation data. The gas turbine sends the GT exhaust gas dust concentration representing the amount of dust on the outlet side to the determination device 1 as operation data. In addition, the dust removal device 110 is provided for the primary cyclone 111 and the secondary cyclone 112, the inlet / outlet differential pressure, the ash output gas temperature, the plenum differential pressure, the S / F high chilled water output temperature, the ash S / F input ash temperature and the discharge. The interval is sent to the determination device 1 as operation data.

  On the other hand, when the operator operates the input unit 15 and inputs an instruction for determining the clogged state of the cyclone in advance, the processing unit 11 starts the clogging determination process. The processing unit 11 first performs a variation determination process. By this variation determination processing, the processing unit 11 uses the operation data from the gas turbine and the dust removing device 110 as comparison data in the operation data table (FIG. 4), and determines whether each operation data has a variation. Since the amount of ash AS differs depending on the coal type and load in the clogging determination process, the processing unit 11 uses the coal type input to the input unit 15 and the APC output from the dust removal device 110 to generate a reference value table. Use the corresponding reference value and deviation.

  When the variation determination process is completed, the processing unit 11 next performs a blockage determination process. By this blockage determination process, the processing unit 11 determines the clogging tendency of the primary cyclone 111 and the secondary cyclone 112 using the operation data table (FIG. 4) updated by the variation determination process. Then, the processing unit 11 displays a message representing the determination result on the display unit 14 and outputs it from the output unit 16.

  In this way, according to this embodiment, the operation data such as the plenum differential pressure is added to the operation data representing the payout interval between the primary cyclone 111 and the secondary cyclone 112 to add the primary cyclone 111 and the secondary cyclone 112. Therefore, it is possible to eliminate individual differences in the determination of clogging of the cyclone by the operator, and to accurately determine the blockage of the primary cyclone 111 and the secondary cyclone 112.

  The embodiment of the present invention has been described in detail above, but the specific configuration is not limited to this embodiment, and even if there is a design change or the like without departing from the gist of the present invention, Included in the invention. For example, when determining the clogging state of the primary cyclone 111 and the secondary cyclone 112, other operation data such as the dust collection efficiency of the primary cyclone 111 and the secondary cyclone 112 may be included in the determination element. Further, in this embodiment, the clogging tendency is determined as the clogged state of the primary cyclone 111 and the secondary cyclone 112, but the deviation of the operation data table (FIG. 4) is changed to change the primary cyclone 111 and the secondary cyclone 112. You may make it determine clogging.

It is a figure which shows the determination apparatus and power plant by embodiment of this invention. It is a figure explaining a primary cyclone. It is a figure which shows an example of a reference value table. It is a figure which shows an example of an operation data table. It is a flowchart which shows fluctuation | variation determination processing. It is a flowchart which shows the blockage determination process of a primary cyclone. It is a flowchart which shows the blockage determination process of a secondary cyclone.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Determination apparatus 11 Processing part (processing means)
12 Storage unit (storage means)
13 interface 14 display unit 15 input unit 16 output unit 110 dust removal device 111 primary cyclone (first-stage cyclone)
112 Secondary cyclone (second stage cyclone)

Claims (4)

The clogged state of the cyclone provided in the power plant that generates power by burning coal and supplies power output to the load was generated by operating data such as the cyclone discharge interval and cyclone plenum differential pressure of the cyclone , and coal combustion. A cyclone clogging determination device that is determined by operation data of a gas turbine that generates power from exhaust gas from which exhaust gas has removed dust from the exhaust gas,
Storage means for storing reference data such as reference values and deviations created based on normal operation data for each coal type and load;
A difference between a plurality of input operation data and a reference value of the reference data of the storage means corresponding to the operation data is compared with a deviation, and when the difference from the reference value is outside the deviation, Fluctuation determination processing means for determining that the reference data has fluctuation;
A blockage determination process for determining the clogged state of the cyclone based on whether or not it is determined by the fluctuation determination processing means that the cyclone delivery interval of the operation data is extended and the cyclone plenum differential pressure is increased. Means,
A cyclone clogging determination device comprising: When the cyclones are connected in two stages,
The operation data includes operation data of the first-stage cyclone and the second-stage cyclone,
In the blockage determination processing means, the first-stage cyclone payout interval of the operation data is extended, the second-stage cyclone payout interval is shortened, and the first-stage cyclone plenum differential pressure is increased. The cyclone clogging determination apparatus according to claim 1 , wherein the clogging state of the first-stage cyclone is determined based on whether or not it is determined. The blockage determination processing means determines whether or not the second-stage cyclone discharge interval of the operation data is extended and the second-stage cyclone plenum differential pressure is determined to be increased. The cyclone clogging determination apparatus according to claim 2 , wherein a clogging state of the eye cyclone is determined. The clogged state of the cyclone provided in the power plant that generates power by burning coal and supplies power output to the load was generated by operating data such as the cyclone discharge interval and cyclone plenum differential pressure of the cyclone , and coal combustion. A method for determining clogging of a cyclone that is determined by operation data of a gas turbine that generates power using exhaust gas from which exhaust gas has removed dust from the exhaust gas,
Reference data such as reference values and deviations created based on normal operation data for each coal type and load are stored.
The difference between the plurality of input operation data and the reference value of the stored reference data corresponding to the operation data is compared with the deviation. When the difference from the reference value is outside the deviation, The reference data is determined to be fluctuating,
Based on whether it is determined that the cyclone delivery interval of the operation data is extended and the cyclone plenum differential pressure is increased, the clogging state of the cyclone is determined.
A method for judging clogging of a cyclone.

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