JP2014052929A - Control device and control method for thermal power plant - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress deterioration of characteristics of a thermal power plant when an operation form or an environment changes.SOLUTION: A control device for a thermal power plant, which generates a first operation signal by referring to a measurement signal, includes an operation result determination part 410 for determining improvement/deterioration of characteristics of the thermal power plant as the result of outputting a first operation signal, a state classification part 420 for classifying the state of the thermal power plant by referring to the measurement signal, and a state storage database 430 for recording the determination result of the operation result determination part and the state of the thermal power plant classified by the state classification part in association with each other. Operation signal generation means continuously outputs the first operation signal currently output to the thermal power plant when the current state of the thermal power plant classified by the state classification part is a state when a second operation signal is generated reaching a state where the characteristics of the thermal power plant are determined to be worse by the operation result determination part.

Description

  The present invention relates to a control device for a thermal power plant. More particularly, the present invention relates to a control apparatus suitable for reducing environmentally hazardous substances discharged from a thermal power plant and reducing fuel consumption.

  In the control plant market for thermal power plants, in order to reduce the running cost of the thermal power plant, there is a demand for technology that realizes reduction of environmental load substances discharged from the thermal power plant and reduction of the flow rate of fuel consumed in the thermal power plant.

  The thermal power plant control device processes a measurement signal representing the state of the thermal power plant obtained from the thermal power plant that is the control target, and calculates an operation signal to be given to the control target. An algorithm for calculating an operation signal is mounted on the control device so that the measurement signal of the thermal power plant satisfies the target value.

  As a control algorithm used for controlling a thermal power plant, there is a PI (proportional / integral) control algorithm. In PI control, a value obtained by multiplying a deviation between a measurement signal of a thermal power plant and its target value by a proportional gain is added to a value obtained by integrating the deviation over time, and an operation signal to be given to a control target is derived. Since the control algorithm using PI control can describe the input / output relationship with a block diagram etc., the causal relationship between input and output is easy to understand. In thermal power plant control, PI control is a stable and safe control algorithm and can be applied. There are many achievements. In PI control, it is possible to reduce environmentally hazardous substances and fuel consumption by appropriately setting control target values. However, when the thermal power plant is operated under conditions that are not assumed in advance, such as a change in the thermal power plant operation mode or an environmental change, an operation such as changing the control algorithm may be required.

  On the other hand, there is adaptive control that automatically corrects / changes the control method in response to changes in the operation form and environment of the thermal power plant. As a thermal power plant control method using a learning algorithm which is one of the methods, there is, for example, Patent Document 1. In this method, the control apparatus includes a learning unit that learns a model for predicting the characteristics of the controlled object and a model input generation method that achieves the target value of the model output. Patent Document 1 describes a control device that learns an operation method for reducing an environmental load substance by learning using a model that simulates a relationship between an operation amount and an emission amount of an environmental load substance.

JP 2007-241624 A

  If the control target value cannot be set in response to changes in the operation form of the thermal power plant or the environment in the control device for the thermal power plant, the operation characteristics of the thermal power plant may be deteriorated by the control. Further, since the thermal power plant is a multivariable interference system, even if one parameter representing the state of the thermal power plant is operated so as to satisfy the target value, the values of the other parameters may deteriorate.

  Even when a thermal power plant control device using a learning algorithm is used, if the accuracy of the model is low, even if the thermal power plant is operated according to the learning result, there is a possibility that desired characteristics cannot be obtained.

  The present invention provides a control device for a thermal power plant that suppresses deterioration of the characteristics of the thermal power plant when the operation form or environment of the thermal power plant changes.

  The control device for a thermal power plant to be disclosed includes an operation signal generation unit that acquires a measurement signal from the thermal power plant, generates a first operation signal of the thermal power plant with reference to the measurement signal, and is generated by the operation signal generation unit. A control device for a thermal power plant that outputs an operation signal of 1 to a thermal power plant, and refers to an operation to determine improvement / deterioration of characteristics of the thermal power plant as a result of outputting the first operational signal with reference to a measurement signal Result determination unit, state classification unit that classifies the state of the thermal power plant with reference to the measurement signal, and state storage database that records the determination result by the operation result determination unit and the state of the thermal power plant classified by the state classification unit in association with each other The operation signal generation means includes a thermal power plan recorded by the operation result determination unit in which the current state of the thermal power plant classified by the state classification unit is recorded in the state storage database. The current first operation signal output to the thermal power plant is continuously output when the second operation signal that has been determined to have deteriorated has been generated. .

  According to the control device and the control method to be disclosed, it is possible to suppress the deterioration of the characteristics of the thermal power plant when the operation form or environment of the thermal power plant is changed.

It is a block diagram of the 1st Example of a control apparatus. It is a flowchart which shows operation | movement of the 1st Example of a control apparatus. It is an image figure which shows the aspect of the data preserve | saved at each database. It is a figure explaining the outline of a thermal power plant. It is a figure explaining operation | movement of the operation result determination part. It is a figure explaining the classification | category by a state classification | category part. It is a figure explaining the classification | category by a state classification | category part. It is a figure explaining operation | movement of the operation signal production | generation part. It is a block diagram of 2nd Example of a control apparatus. It is a flowchart which shows operation | movement of the 2nd Example of a control apparatus. It is a figure explaining the data preserve | saved at the model database, the example of a model, and the relationship between a model input and a model output. It is a block diagram of 3rd Example of a control apparatus. It is a figure explaining operation | movement of the 3rd Example of a control apparatus.

  The thermal power plant control apparatus of the present invention will be described with reference to the drawings.

  FIG. 1 is a configuration diagram of a first embodiment of a control device for a thermal power plant. The control device 200 controls the thermal power plant 100 as a control target.

  The control device 200 includes an operation signal generation unit 300, an operation result determination unit 410, and a state classification unit 420. The control device 200 has a measurement signal database 230, an operation signal database 240, and a state storage database 430 as databases. In this embodiment, the operation result determination unit 410, the state classification unit 420, and the storage state database 430 are collectively referred to as a state storage unit 400.

  The control device 200 has an external input interface 210 and an external output interface 220 as interfaces with the outside. The control device 200 inputs the measurement signal 1 from the thermal power plant 100 to the control device 200 via the external input interface 210. In addition, the operation signal 5 is output to the thermal power plant 100 via the external output interface 220.

  The measurement signal 2 input via the external input interface 210 is stored in the measurement signal database 230. The operation signal 4 generated by the operation signal generation unit 300 is output to the external output interface 220 and is stored in the operation signal database 240.

  The state storage unit 400 processes the measurement signal 3 stored in the measurement signal database 230 and generates state information 8 referred to by the operation signal generation unit 300. The operation result determination unit 410 constituting the state storage unit 400 refers to the measurement signal 3 to determine whether the characteristics of the thermal power plant 100 have improved or deteriorated as a result of outputting the operation signal 5, and the determination result (improvement) / Deterioration) is output to the state classification unit 420 as the operation result determination information 6 and also output to the storage state database 430. The operation of the operation result determination unit 410 will be described later with reference to FIG.

  The state classification unit 420 constituting the state storage unit 400 refers to the measurement signal 3 and classifies the state of the thermal power plant 100. The state classification unit 420 classifies the state of the thermal power plant 100 using a clustering technique such as adaptive resonance theory or vector quantization. The state classification unit 420 outputs the state classification result information 7 to the state storage database 430. The operation of the state classification unit 420 will be described later with reference to FIGS.

  The state storage database 430 constituting the state storage unit 400 stores operation result determination information 6 and state classification result information 7 as state information 8.

  The operation signal generation unit 300 generates the operation signal 4 with reference to the state information 8 stored in the state storage database 430. However, when the state information 8 in which the characteristics of the thermal power plant 100 have deteriorated due to the generated operation signal 4 is stored in the state storage database 430, the state when the operation signal 4 included in the state information 8 is generated is When the current state of the thermal power plant 100 is the same (not necessarily the same, and the same within a predetermined range), the value of the new operation signal 4 is not generated and is currently output to the thermal power plant 100. By continuously outputting the value of the operation signal 4 that is present, deterioration of the characteristics of the thermal power plant 100 is avoided. In other words, the operation signal generation unit 300 has reached the state where the current state of the thermal power plant 100 is recorded in the state storage database 430 and the operation result determination unit 410 has determined that the characteristics of the thermal power plant 100 have deteriorated. When the operation signal 4 is generated, the current operation signal 4 output to the thermal power plant 100 is continuously output. The operation of the operation signal generation unit 300 will be described later with reference to FIG.

  The operator of the thermal power plant 100 generates the maintenance tool input signal 51 using the external input device 900 including the keyboard 901 and the mouse 902, and inputs the signal 51 to the maintenance tool 910. The information of each database of the control device 200 is displayed on the image display device 950.

  The maintenance tool 910 includes an external input interface 920, a data transmission / reception processing unit 930, and an external output interface 940.

  The maintenance tool input signal 51 generated by the external input device 900 is input to the maintenance tool 910 via the external input interface 920. The data transmission / reception processing unit 930 of the maintenance tool 910 acquires the database information 50 from each database of the control device 200 according to the information of the maintenance tool input signal 52 from the external input interface 920.

  The data transmission / reception processing unit 930 outputs a maintenance tool output signal 53 obtained as a result of processing the database information 50 to the external output interface 940. The maintenance tool output signal 54 from the external output interface 940 is displayed on the image display device 950.

  In the control device 200 according to the present embodiment, the measurement signal database 230, the operation signal database 240, the operation signal generation unit 300, and the state storage unit 400 are provided inside the control device 200. May be provided outside the control device 200.

  FIG. 2 is a flowchart showing the operation of the control device 200. In step 1000, the operation signal generator 300 is operated to generate the operation signal 4 with reference to the measurement signal 3 stored in the measurement signal database 230 and the state information 8 stored in the state storage database 430. .

  In step 1010, the state storage unit 400 is operated, and the state of characteristics (improvement / deterioration of characteristics) of the thermal power plant 100 is stored in the state storage database 430.

  In step 1020, an end determination is performed. If YES, the operation of the control device 200 is ended. If NO, the process returns to step 1000. In the end determination, the operation of the control device 200 is ended when the operator of the thermal power plant 100 performs an operation to stop the control device 200.

  In FIG. 2, the processing from step 1000 is repeated immediately after the end determination of step 1020, but in actuality, the processing of step 1000 is performed at every predetermined time interval (sampling cycle described in FIG. 3). Control to start.

  FIG. 3 is a diagram for explaining an aspect of data stored in each database of the control device 200 as an image displayed on the image display device 950.

  As shown in FIG. 3 (a), the measurement signal database 230 indicates the value of the measurement signal 2 (in the figure, data items A, B, and C), which are operation data of the thermal power plant 100, and the sampling period (vertical axis). Save every time. In addition, although illustration is abbreviate | omitted, the operation signal database 240 preserve | saves the value of the operation signal of the thermal power plant 100 for every sampling period in the same format as the measurement signal database 230. Each data stored in the measurement signal database 230 and the operation signal database 240 is associated by time data.

  By using scroll boxes 232 and 233 that can be moved vertically and horizontally on the display screen 231 displaying the contents of the measurement signal database 230, a wide range of data can be scroll-displayed.

  As shown in FIG. 3B, the storage state database 430 includes a state number indicating the state classified by the state classification unit 420 and the operation result determination information 6 generated by the operation result determination unit 410 (operation result in the figure). , Values before and after the operation of the measurement signal 3 as an evaluation item for obtaining the operation result, and its increase / decrease, values before and after the operation of the operation signal 4 which is the operation amount leading to the operation result, etc. . In addition, (circle) described in the operation result column of FIG.3 (b) means the improvement of the characteristic of the thermal power plant 100, and x means deterioration.

  FIG. 4 is a diagram for explaining the outline of the thermal power plant 100. First, the power generation mechanism of the thermal power plant 100 will be described with reference to FIG.

  A boiler 101 constituting the thermal power plant 100 is provided with a burner 102 for supplying fuel (pulverized coal) finely pulverized by a mill 110, primary air for conveying pulverized coal, and secondary air for adjusting combustion. The pulverized coal supplied through the burner 102 is combusted inside the boiler 101. The pulverized coal and the primary air are led from the pipe 134 and the secondary air is led from the pipe 141 to the burner 102.

  The boiler 101 is provided with an after air port 103 for introducing after-air for two-stage combustion into the boiler 101, and the after air is guided to the after air port 103 from the pipe 142.

  The high-temperature combustion gas generated by the combustion of the pulverized coal flows downstream along the path inside the boiler 101 (thick line with an arrow in the figure), and then heat exchanges in the heat exchanger 106 arranged in the boiler 101. And passes through the air heater 104. The gas that has passed through the air heater 104 is discharged into the atmosphere from the chimney after being subjected to exhaust gas treatment.

  The feed water circulating through the heat exchanger 106 of the boiler 101 is supplied through the feed water pump 105. The feed water supplied to the heat exchanger 106 is heated by the combustion gas flowing down the boiler 101 in the heat exchanger 106 to become high-temperature and high-pressure steam. In this embodiment, the number of heat exchangers is one, but a plurality of heat exchangers may be arranged.

  The high-temperature and high-pressure steam that has passed through the heat exchanger 106 is guided to the steam turbine 108 via the turbine governor 107, and the steam turbine 108 is driven by the energy of the steam to generate power by the generator 109.

  In the thermal power plant 100, various measuring devices that detect the operating state of the thermal power plant 100 are arranged, and the measurement signal of the thermal power plant 100 acquired from these measuring devices is input to the control device 200 as the measurement signal 1. Is done. For example, FIG. 4A shows a flow rate measuring device 150, a temperature measuring device 151, a pressure measuring device 152, a power generation output measuring device 153, and a concentration measuring device 154.

  The flow rate measuring device 150 measures the flow rate of the feed water supplied from the feed water pump 105 to the heat exchanger 106 of the boiler 101. The temperature measuring device 151 and the pressure measuring device 152 measure the temperature and pressure of the steam supplied from the heat exchanger 106 to the steam turbine 108.

  The amount of power generated by the power generator 109 is measured by a power generation output measuring device 153. The concentration of components (CO, NOx, etc.) contained in the combustion gas passing through the boiler 101 is measured by a concentration measuring device 154 provided on the downstream side of the boiler 101.

  In general, many measuring instruments other than those shown in FIG. 4 are arranged in the thermal power plant, but the illustration is omitted here. The measurement signal 1 measured by these measuring instruments is shown as data items A, B, and C in FIG.

  Next, the paths of primary air and secondary air that are input from the burner 102 into the boiler 101 and the path of after-air that is input from the after-air port 103 will be described.

  The primary air is guided from the fan 120 to the pipe 130 and branched into a pipe 132 that passes through the air heater 104 installed on the downstream side of the boiler 101 and a pipe 131 that bypasses the air heater 104 without passing through the air. Then, it merges again in the pipe 133 and is guided to the mill 110 installed on the upstream side of the burner 102.

  The primary air passing through the air heater 104 through the pipe 132 is heated by the combustion gas flowing down the boiler 101. Using this primary air, the differential charcoal crushed in the mill 110 is conveyed to the burner 102 together with the primary air.

  The secondary air and after air are led from the fan 121 to the pipe 140 and heated by the air heater 104 in the same manner as the primary air, and then branched into the secondary air pipe 141 and the after air pipe 142. Then, they are led to the burner 102 and the after-air port 103, respectively.

  FIG. 4B is a diagram in which the air heater 104 and the piping constituting the thermal power plant 100 are extracted. As shown in FIG. 4B, air dampers 160, 161, 162, and 163 are disposed in the pipes 131, 132, 141, and 142, respectively. By operating these air dampers individually, the area through which the air passes through the pipes 131, 132, 141, 142 can be changed, and the flow rate of air passing through the pipes 131, 132, 141, 142 can be adjusted individually.

  The operation signal 5 generated by the control device 200 is a signal for operating devices such as the water supply pump 105, the mill 110, and the air dampers 160, 161, 162, and 163. In this embodiment, devices such as the water supply pump 105, the mill 110, and the air dampers 160, 161, 162, and 163 are referred to as operation ends, and command signals necessary for operating them are referred to as operation signals.

  In addition, when fuel such as combustion or fuel such as pulverized coal is introduced into the boiler 101, a function of moving the discharge angle up, down, left and right is added to the burner 102 and the after-air port 103 to control these angles. It can also be included in signal 5. Further, although not shown in FIG. 4, the exhaust gas can be guided to the lower part of the furnace of the boiler 101 (exhaust gas recirculation).

  FIG. 5 is a diagram for explaining the operation of the operation result determination unit 410 provided in the control device 200 of the thermal power plant 100 of the present embodiment. Here, as an evaluation item for obtaining the operation result, the NOx concentration of the measurement signal 3 will be described as an example.

  In the operation result determination unit 410, by evaluating the change in the value of the evaluation item for evaluating the characteristics of the thermal power plant 100 before and after the operation signal 5 is changed, the characteristics of the thermal power plant 100 are improved as a result of the operation. Evaluate whether it has deteriorated (improvement / deterioration).

  By comparing the period A and the period B in FIG. 5, it can be seen that changing the value of the operation signal 5 increases the NOx concentration, which is one of the evaluation items, and deteriorates the characteristics of the thermal power plant 100.

  Further, after changing the value of the operation signal 5, the amount of change in the value of the evaluation item (NOx concentration) is obtained using the NOx concentration value (which may be an average value for a predetermined period) after being settled. For example, the amount of change in the value of the evaluation item according to the change in the value of the operation signal 5 is obtained using the average value of the NOx concentrations in the periods A to C.

  The operation result information 6 obtained by the operation result determination unit 410 is stored in the storage state database 431 in the format shown in FIG. In FIG. 3B, as described above, the value of the evaluation item before the change of the operation signal 5, the value of the evaluation item after the change, the change amount of the evaluation item as the increase / decrease, and before and after the change of the operation signal 5 It is shown in association with the value.

  In addition, although NOx concentration is shown as an example of the evaluation item corresponding to the operation signal in FIG. 5, reduction of this NOx concentration results in reduction of environmental load substances discharged from the thermal power plant 100.

  Although the NOx concentration discharged from the thermal power plant 100 has been described, various components contained in the combustion gas such as CO concentration, carbon dioxide concentration, sulfide oxide concentration, mercury concentration, etc. discharged from the thermal power plant 100 are also described. It may be an evaluation item. Specifically, the evaluation item is not limited to one component, but a plurality of components or a combination of a plurality of components.

  Furthermore, the fuel flow rate consumed by the thermal power plant 100 can be reduced by including the fuel flow rate and the unburned fuel content in the evaluation items.

  In addition, the operation target device can be included in the operation end for operating the thermal power plant 100 using the opening degree of the air damper, the air flow rate, the air temperature, the fuel flow rate, the exhaust gas recirculation flow rate, and the like as items of the operation signal.

  Next, the classification of the measurement signal 3 by the state classification unit 420 provided in the control device 200 of the thermal power plant 100 of the present embodiment will be described with reference to FIGS.

  A case where adaptive resonance theory (ART) is applied to data classification by the state classification unit 420 of the control device 200 of the thermal power plant 100 of the present embodiment will be described. Note that other clustering methods such as vector quantization can be used for data classification.

  As shown in FIG. 6A, the state classification unit 420 performs data classification by the data preprocessing device 610 and the ART module 620. The data preprocessing device 610 converts the operation data (measurement signal 3) into input data of the ART module 620.

  Hereinafter, a procedure for data classification by the data preprocessing device 610 and the ART module 620 will be described.

  First, the data preprocessing device 610 normalizes data (measurement signal 3) for each measurement item. Data including the data Nxi (n) obtained by normalizing the measurement signal 3 and the complement of the normalized data CNxi (n) (= 1−Nxi (n)) is defined as input data Ii (n). This input data Ii (n) is input to the ART module 620.

  In the ART module 620, the measurement signal 3 is classified into a plurality of categories.

  The ART module 620 includes an F0 layer 621, an F1 layer 622, an F2 layer 623, a memory 624, and a selection subsystem 625, which are coupled to each other. The F1 layer 622 and the F2 layer 623 are connected via a weighting factor. The weighting factor represents the prototype (prototype) of the category into which the input data is classified. Here, the prototype represents a representative value of the category.

  Next, the algorithm of the ART module 620 will be described.

  The outline of the algorithm when input data is input from the data preprocessing device 610 to the ART module 620 is as shown in the following processing 1 to processing 5.

  Process 1: The input data is normalized again by the F0 layer 621 to remove noise.

  Process 2: A suitable category candidate is selected by comparing the input data input to the F1 layer 622 with a weighting factor. Specifically, a category having a small difference between the input data and the weighting coefficient is set as a candidate.

  Process 3: The validity of the category selected by the selection subsystem 625 is evaluated by comparison with a predetermined parameter ρ. If it is determined to be valid (parameter ρ or more), the input data is classified into the category, and the process proceeds to process 4. On the other hand, if it is not determined to be valid (less than parameter ρ), the category is reset as a candidate, and a category candidate is selected from other categories (repeat processing 2). Increasing the value of parameter ρ makes the category classification finer, and decreasing the value of ρ makes the classification coarse. This parameter ρ is referred to as a vigilance parameter.

  Process 4: When all the existing categories are reset as candidates in Process 3, it is determined that the input data belongs to the new category, and a new weighting factor representing the prototype of the new category is generated.

  Process 5: When input data is classified into category J, weight coefficient WJ (new) corresponding to category J uses past weight coefficient WJ (old) and input data p (or data derived from input data). Is updated by equation (1).

  Here, Kw is a learning rate parameter (0 <Kw <1), and is a value that determines the degree to which the input vector is reflected in the new weighting factor.

  The arithmetic expressions of Expression (1) and Expressions (2) to (12) described later are incorporated in the ART module 620.

  The feature of the data classification algorithm of the ART module 620 is the processing 4 described above.

  In the process 4, when input data different from the category at the time of learning is input, a new category can be recorded without changing the recorded category. Therefore, it is possible to record a new category while recording a category learned in the past.

  As described above, when driving data that has not been learned in the past is given as input data in advance, the ART module 620 learns the given category. Therefore, when new input data is input to the learned ART module 620, it is possible to determine which category in the past is close by the above algorithm. If the category has never been experienced before, it is classified into a new category.

FIG. 6B is a block diagram showing the configuration of the F0 layer 621. In the F0 layer 621, the input data I _i is normalized again at each time to create a normalized input vector u _{i / 0} that is input to the F1 layer 621 and the selection subsystem 625.

First, w _{i / 0} is calculated from input data I _{i according} to equation (2). Here, a is a constant.

Next, x _{i / 0} obtained by normalizing w _{i / 0} is calculated using equation (3). Here, || · || is a symbol representing the norm.

Then, using equation (4), calculates the v _{i / 0} obtained by removing noise from x _{i / 0.} However, θ is a constant for removing noise. Since the minute value becomes 0 by the calculation of the equation (4), noise of the input data is removed.

Finally, a normalized input vector u _{i / 0} is obtained using equation (5). u _{i / 0} is input to the F1 layer.

FIG. 6C is a block diagram showing the configuration of the F1 layer 622. In the F1 layer 622, u _{i / 0} obtained by the equation (5) is held as a short-term memory, and p _i to be input to the F2 layer 623 is calculated. The formulas for calculating the F1 layer 622 are collectively shown in formulas (6) to (12). Here, a and b are constants, f (·) is a function shown in Expression (4), and T _j is a fitness calculated by the F2 layer 623.

  However,

  Next, classification of the measurement signal 3 will be described with reference to FIG.

  FIG. 7A shows the measurement signal 3 (item A, item B) acquired from the thermal power plant 100 by the state classification unit 420 as a category (here, the category determined from the relationship between the values of the items A and B). It is a figure explaining the result classified into (1). The horizontal axis is time, and the vertical axis is measurement signal and category number. FIG. 7B is a diagram illustrating an example of a classification result obtained by classifying the measurement signals 3 of the thermal power plant 100 into categories.

  FIG. 7B shows, as an example, two items (item A and item B) of the measurement signal 3 displayed as evaluation items, which are represented by a two-dimensional graph. Further, the vertical axis and the horizontal axis indicate the measurement signals 3 of the respective items normalized.

  The measurement signal 3 is classified into a plurality of categories 630 (circles shown in FIG. 7B) by the ART module 620. One circle corresponds to one category determined from the relationship between the values of item A and item B.

  In FIG. 7B, the measurement signals 3 are classified into four categories determined from the relationship between the values of the items A and B. Specifically, category number 1 is a group in which item A has a large value and item B has a small value, category number 2 is a group in which both items A and B have small values, and category number 3 is a value in item A Is a group in which the value of item B is large, and category number 4 is a group in which the values of item A and item B are both large.

  Although an example in which two measurement signals 3 are classified into categories has been described, three or more measurement signals 3 are classified into categories using multidimensional coordinates.

  The state classification unit 420 includes NOx concentration, CO concentration, carbon dioxide concentration, sulfide oxide concentration, mercury concentration, air flow front / rear ratio, air damper opening, air flow rate, air temperature, fuel flow rate, exhaust gas recirculation flow rate, Measurement signals 3 relating to coal combustion, such as burner air ratio, coal composition, air flow rate to coal flow rate ratio (C / A), and power generation output, are input as evaluation items.

  FIG. 8 is a diagram for explaining the operation of the operation signal generation unit 300 of the control device 200. As a result of changing the operation signal 5 from C1 to C2 in the state classified into the category 1 by the state classification unit 420, the evaluation item As an example, the NOx concentration, which is the measurement signal 3, increases from D1 to D2, and the characteristics of the thermal power plant 100 deteriorate. By experiencing this series of operations, the operation result determination information 6 when the operation signal 5 is changed from C1 to C2 in the category 1 state is recorded in the state storage database 430 as x (deteriorated). Therefore, when the same category 1 state is entered next, the operation signal generation unit 300 does not change the operation signal 4 from C1 to C2 (C1 is continued without generating C2 as the operation signal 4).

  In the present embodiment, the fact that the characteristics of the thermal power plant 100 have deteriorated as a result of the operation by the control device 200 is stored, and the same operation that leads to the deterioration of the characteristics of the thermal power plant 100 is not reproduced with reference to the stored contents. By avoiding an operation that deteriorates the characteristics of the thermal power plant 100, the environmental load of the thermal power plant can be reduced, and the fuel consumption can be reduced.

  Further, the control device 200 displays the contents of the data stored in the state storage database 431 shown in FIG. 3B and the trend graph of the time series data shown in FIG. 8 on the image display device 950. Whether or not the operation is effective can be provided to the operator of the thermal power plant 100.

  FIG. 9 is a configuration diagram of a second embodiment of the control device 200 of the thermal power plant 100. The control device 200 of the thermal power plant 100 of the present embodiment has a configuration in which an operation method learning unit 500 is added to the control device 200 of the thermal power plant 100 of the first embodiment.

  The operation method learning unit 500 includes a model 520, an evaluation value calculation unit 530, a calculation unit of the learning unit 540, a model database 510, and a learning information database 550.

  The operation method learning unit 500 refers to the measurement signal 3 to obtain learning information database information 16.

  The learning information database information 16 stored in the learning information database 550 is generated by the model 520, the evaluation value calculation unit 530, and the learning unit 540.

  The model 520 simulates the control characteristics of the thermal power plant 100. The operation signal 5 generated by the control apparatus 200 is output to the thermal power plant 100, and the control apparatus 200 inputs the measurement signal 1 that is the control result. The operation of the thermal power plant 100 that outputs the measurement signal 1 in response to the operation signal 5 from the control device 200 is simulated by operating the learning unit 540 and the model 520 in combination. That is, the model 520 receives the model input 13 generated by the learning unit 540, simulates the control characteristics of the thermal power plant 100, and outputs the model output 11 as the control result to the learning unit 540.

  The model 520 refers to the model database information 10 stored in the model database 510 and obtains the model output 11 corresponding to the model input 13. The model 520 is a statistical model such as a neural network or a physical model of the thermal power plant 100, for example.

  The model database 510 stores the measurement signal 3, model parameters necessary for constructing the model 520, and the like.

  The learning unit 540 learns how to generate the model input 13 so that the model output 11 calculated by the model 520 has a desired value. Parameters used for learning, such as a target value of the model output 11, are stored in the learning information database 550, and are learned by the learning unit 540 using the learning information database information 15 stored in the learning information database 550.

  As a method of implementing the learning unit 540, there is reinforcement learning. In the reinforcement learning, the model input 13 is generated by trial and error in the initial stage of learning. Thereafter, as the learning proceeds, the model input 13 is generated so that the model output 11 becomes a desired value. As such a learning algorithm, “Reinforcement Learning” (Co-translation by Sadayoshi Mikami and Masaaki Minagawa, published by Morikita Publishing Co., Ltd., December 20, 2000, pages 142 to 172, pages 247 to 253) ) Gives a positive evaluation value when the measurement signal achieves the driving target value, and based on this evaluation value, an operation signal generation method using algorithms such as Actor-Critic, Q-learning, and real-time dynamic programming The method of learning is described. In FIG. 9, in order to calculate such an evaluation value, an evaluation value calculation unit 530 is provided.

  The learning unit 540 can apply various optimization methods such as an evolutionary calculation method in addition to the method described above. The learning information database information 14 that is a result of learning by the learning unit 540 is stored in the learning information database 550.

  The operation signal generation unit 300 refers to the learning information database information 16 stored in the learning information database 550 in order to generate the operation signal 4. Thereby, the operation signal generator 300 generates the operation signal 4 reflecting the learning result.

  FIG. 10 is a flowchart showing the operation of the control device 200 of this embodiment.

  In step 1100, it is determined whether or not the operation method learning unit 500 is to be operated. If YES, the process proceeds to step 1110, and if NO, the process proceeds to step 1120.

  In step 1110, the operation method learning unit 500 is operated to create the learning information database information 14 and stored in the learning information database 550.

  In step 1120, the operation signal generation unit 300 is operated and the measurement signal 3 stored in the measurement signal database 230, the learning information database information 16 stored in the learning information database 550, and the state storage database 430 are stored. The operation signal 4 is generated with reference to the status information 8 that is present.

  In step 1130, the state storage unit 400 is operated, and the state of characteristics (improvement / deterioration of characteristics) of the thermal power plant 100 is stored in the storage state database 430.

In step 1140, an end determination is performed. If YES, the operation of the control device 200 is ended, and if NO, the process returns to step 1100. In the end determination, the operation of the control device 200 is ended when the operator of the thermal power plant 100 performs an operation to stop the control device 200.
FIG. 11 is a diagram illustrating data stored in the model database 510 according to the present embodiment, examples of models, and a relationship between model inputs and model outputs.

  FIG. 11A is a diagram for explaining the mode of data stored in the model database 510 as an image displayed on the image display device 950. As shown in FIG. 11A, the relationship between the model input and the model output is stored. Each of the data items of the model input and the model output is a data item of the operation signal 4 and the measurement signal 3. The relationship between the model input and the model output is created by using past plant operation results stored in the measurement signal database 230. Although not shown in FIG. 9, data on the relationship between model input and model output may be created using a physical model that simulates the thermal power plant 100.

  FIG. 11B illustrates an example of the model 520. FIG. 11B shows an example in which the model 520 is configured by a neural network model.

  FIG. 11C illustrates the relationship between model input and model output. By using a neural network model, it is possible to interpolate discrete values stored in the model database 510 and calculate a change in model output with respect to a continuous change in model input.

  Since the controller of this embodiment classifies the state of the characteristics of the thermal power plant 100 using more data items than the model (considering data items as factors not reflected in the model). The state that cannot be simulated by the model can be stored. An operation that deteriorates characteristics due to this can be avoided. Compared with model learning alone, system reliability can be improved.

  FIG. 12 is a configuration diagram of a third embodiment of the control device for the thermal power plant. The control device 200 of the thermal power plant 100 of the present embodiment has a configuration in which a feature quantity extraction unit 440 is added to the state storage unit 400 of the control device 200 of the thermal power plant 100 of the second embodiment.

  The feature amount extraction unit 440 compares the case where the characteristics of the thermal power plant 100 are improved and the case where the characteristics of the thermal power plant 100 are deteriorated as a result of the operation, and extracts the data item of the operation signal 5 that causes a characteristic difference in the state of the thermal power plant 100. By adding the extracted data items to the model input items of the model 520, the model accuracy is improved.

  FIG. 13 is a diagram for explaining the operation of the control device 200 in this embodiment.

  FIG. 13A is a diagram for explaining the operation of the feature amount extraction unit 440. FIG. 13A shows the categories classified by the operation result determination unit 410 stored in the state storage database 430 with the items A and B as coordinates as the data items of the operation signal 5. .

  The values of item A and item B corresponding to the category in which the characteristics of the thermal power plant 100 have deteriorated are the closest when expressed as shown in FIG. 13A (closest is the Euclidean distance is short, in other words, , The difference between the values of item A and item B is the smallest, the similarity is high), and the category with improved characteristics of the thermal power plant 100 is extracted. Next, the distance between the values of the items A and B corresponding to the category in which the characteristics of the thermal power plant 100 have deteriorated and the center of the extracted category is obtained, and the data item that maximizes the contribution to this distance is selected. In other words, in the example of FIG. 13A, the difference between the item A contribution (the value of the item A corresponding to the category in which the characteristics of the thermal power plant 100 deteriorated and the value of the item A corresponding to the center of the extracted category). ) And the item B contribution (the difference between the value of the item B corresponding to the category in which the characteristics of the thermal power plant 100 have deteriorated and the value of the item B corresponding to the center of the extracted category) are the two sides, and the distance is the hypotenuse In the right triangle, the data item A of the operation signal 5 having a large contribution is selected.

  FIG. 13B is a diagram for explaining a state in which the data item extracted by the feature amount extraction unit 440 is added to the model input of the model 520. By adding the data item of the operation signal extracted by the feature amount extraction unit 440 to the input item of the neural network, the model can be modified to simulate the relationship between the extracted data item and the CO concentration, NOx concentration, and unburned content.

  By using the control device 200 of the present embodiment, factors (data items) that cannot be simulated by the model are extracted, and the model is improved by taking the extracted factors into consideration, thereby improving the accuracy of the model. By learning using a model with improved accuracy, it is possible to learn an operation method that is effective in reducing the environmental load of a thermal power plant and reducing fuel consumption. In addition, the order of the model (the number of types of data items) can be minimized, and learning can be performed in a time applicable to the actual device.

  In addition, this invention is not limited to an above-described Example, Various modifications are included. For example, the above-described embodiments are described in detail for easy understanding, and are not necessarily limited to those having all the configurations described. Moreover, although the case where the thermal power plant was made into the control object was described in the present Example, it can also be used for various plants, such as a nuclear power plant and a hydraulic power plant.

  Each of the above-described configurations, functions, processing units, processing means, and the like may be realized by hardware by designing a part or all of them with an integrated circuit. Each of the above-described configurations, functions, and the like may be realized by software that interprets and executes a program that realizes each function. Information such as programs, tables, files, measurement signals, and calculation information for realizing each function can be stored in a storage device such as a memory or a hard disk, or a storage medium such as an IC card, an SD card, or a DVD. Therefore, each process and each configuration can be realized as a processing unit or a program module.

  In addition, information lines indicate what is considered necessary for the explanation, and not all control lines and information lines on the product are necessarily shown. In practice, it may be considered that almost all the components are connected to each other.

1, 2, 3, ... measurement signal, 4, 5 ... operation signal, 6 ... operation result determination result information, 7 ... state classification result information, 8 ... state information, 9, 10 ... model database information, 11 ... model output, DESCRIPTION OF SYMBOLS 12 ... Evaluation value, 13 ... Model input, 14, 15, 16 ... Learning information database information, 17 ... Feature quantity extraction result information, 50 ... Database information, 51, 52 ... Maintenance tool input signal, 53, 54 ... Maintenance tool output Signal: 100 ... Thermal power plant, 200 ... Control device, 210 ... External input interface, 220 ... External output interface, 230 ... Measurement signal database, 240 ... Operation signal database, 300 ... Operation signal generation means, 400 ... State storage unit, 410 ... operation result determination unit, 420 ... state classification unit, 430 ... state storage database, 440 ... feature quantity extraction unit, 500 ... Production method learning unit, 510 ... model database, 520 ... model, 530 ... evaluation value calculation unit, 540 ... learning unit, 550 ... learning information database, 900 ... external input device, 901 ... keyboard, 902 ... mouse, 910 ... maintenance Tool, 920 ... external input interface, 930 ... data transmission / reception processing unit, 940 ... external output interface, 950 ... image display device

Claims (12)

An operation signal generation unit that generates a first operation signal of the thermal power plant with reference to a measurement signal acquired from the thermal power plant, and outputs the first operation signal generated by the operation signal generation unit to the thermal power plant A control device for the thermal power plant,
An operation result determination unit that determines improvement / deterioration of characteristics of the thermal power plant as a result of outputting the first operation signal with reference to the measurement signal,
A state classification unit that classifies the state of the thermal power plant with reference to the measurement signal, and a state memory that records the determination result by the operation result determination unit and the state of the thermal power plant classified by the state classification unit in association with each other With a database,
The operation signal generation means determines that the current state of the thermal power plant classified by the state classification unit is recorded in the state storage database, and that the characteristics of the thermal power plant have deteriorated by the operation result determination unit. A thermal power plant that continuously outputs the current first operational signal that is being output to the thermal power plant when the second operational signal that has reached the state is generated. Control device. The thermal power plant control device according to claim 1, further comprising: a model that simulates the characteristics of the thermal power plant; and a learning unit that learns an operation method for improving the characteristics of the thermal power plant targeting the model. ,
The learning unit learns a method of generating an input signal to be input to the model so that the output signal of the model satisfies a preset target,
The operation signal generation unit generates the first operation signal of the thermal power plant by referring to the output signal of the model together with the measurement signal. An operation signal generation unit that generates a first operation signal of the thermal power plant with reference to a measurement signal acquired from the thermal power plant, and outputs the first operation signal generated by the operation signal generation unit to the thermal power plant A control device for the thermal power plant,
An operation result determination unit that determines improvement / deterioration of characteristics of the thermal power plant as a result of outputting the first operation signal with reference to the measurement signal,
A state classification unit for classifying the state of the thermal power plant with reference to the measurement signal;
A state storage database that records the determination result by the operation result determination unit and the state of the thermal power plant classified by the state classification unit in association with each other;
A model that simulates the characteristics of the thermal power plant,
A learning unit that learns an operation method for improving the characteristics of the thermal power plant for the model, and the state classification unit when the characteristics of the thermal power plant are improved and when the characteristics of the thermal power plant are deteriorated Comparing the classification results according to the above, extracting the data item of the first operation signal that causes a characteristic difference in the state of the thermal power plant, and adding the extracted data item to the input signal of the model With an extractor,
The learning unit learns the generation method of the input signal to which the data item is added by the feature amount extraction unit, which is input to the model so that the output signal of the model satisfies a preset target.
The operation signal generating means generates the first operation signal of the thermal power plant by using the output signal of the model together with the measurement signal. A control device for a thermal power plant according to claim 3,
The operation signal generation unit generates the first operation signal of the thermal power plant using the output signal of the model in addition to the measurement signal, and the current state of the thermal power plant is the state storage database. Is output to the thermal power plant when the second operation signal is generated when the operation result determination unit has reached the state where it is determined that the characteristics of the thermal power plant have deteriorated. A control device for a thermal power plant, wherein the current operation signal is continuously output. In the control apparatus of the thermal power plant of any one of Claims 3-4,
In the feature amount extraction unit, the second classification result when the thermal power plant characteristic is improved, which is closest to the data belonging to the first classification result by the state classification unit when the thermal power plant characteristic is deteriorated, is obtained. Extract and
The distance between the value of the data and the center of the classification result when the thermal power plant characteristics are improved, and the first operation signal that maximizes the contribution to this distance is extracted. Control device. In the control apparatus of the thermal power plant of any one of Claims 1-5,
In the state classification section, the measurement signals, NOx concentration, CO concentration, carbon dioxide concentration, sulfide oxide concentration, mercury concentration, air flow front / rear ratio, air damper opening, air flow rate, air temperature, fuel flow rate, The state of the thermal power plant is classified by referring to at least one data item of exhaust gas recirculation flow rate, burner air ratio, coal composition, air flow rate to coal flow rate (C / A), and power generation output. Thermal power plant control equipment. In the control apparatus of the thermal power plant of any one of Claims 1-6,
In the state storage database, in addition to the determination result by the operation result determination unit and the state of the thermal power plant classified by the state classification unit, the first operation signal before and after changing the first operation signal Storing the value and the value of the measurement signal as an evaluation item before and after changing the first operation signal,
Changes in the value of the first operation signal before and after changing the first operation signal and the measurement signal as evaluation items before and after changing the first operation signal, which are stored in the state storage database A control device for a thermal power plant, wherein a change in the value of the engine is displayed in association with the image display device. In the control apparatus of the thermal power plant of any one of Claims 2-7,
The model is configured as a statistical model, and the model inputs at least the opening degree of the air damper of the thermal power plant, and the model outputs at least one of CO concentration, NOx concentration, and unburned amount discharged from the thermal power plant. A control device for a thermal power plant. In the control apparatus of the thermal power plant of any one of Claims 1-8,
An image display device that displays the determination result by the operation result determination unit and the state of the thermal power plant classified by the state classification unit, the measurement signal, and the trend graph of the first operation signal, which are stored in the state storage database A control device for a thermal power plant, characterized in that: A thermal power plant by a control device having a state storage database that generates a first operation signal of the thermal power plant with reference to a measurement signal acquired from the thermal power plant and outputs the generated first operational signal to the thermal power plant The control method includes:
With reference to the measurement signal, determine the improvement / deterioration of characteristics of the thermal power plant as a result of outputting the first operation signal,
Classifying the state of the thermal power plant with reference to the measurement signal;
Corresponding to the determination result of improvement / deterioration of the characteristics of the thermal power plant and the state of the thermal power plant classified, recorded in the state storage database,
The current state of the classified thermal power plant is a state when a second operation signal that has been recorded in the state storage database and has been determined to have deteriorated the characteristics of the thermal power plant is generated. Sometimes, the thermal plant control method is characterized in that the current first operation signal output to the thermal plant is continuously output. A thermal power plant control method according to claim 10,
The control device has a model that simulates the characteristics of the thermal power plant,
Learning how to generate an input signal to be input to the model so that the output signal of the model satisfies a preset goal,
A method for controlling a thermal power plant, wherein the first operation signal of the thermal power plant is generated by referring to the output signal of the model together with the measurement signal. The thermal power plant control method according to claim 11, wherein the control device includes:
Learning the operation method for improving the characteristics of the thermal power plant targeting the model,
The classification result of the state of the thermal power plant when the characteristic of the thermal power plant is improved and when the characteristic of the thermal power plant is deteriorated, the characteristic difference in the state of the thermal power plant is generated. Extract the operation signal data item of
A method for controlling a thermal power plant, wherein the extracted data item is added to the input signal of the model.

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