JP6966307B2 - Auxiliary power determination device, plant, auxiliary power determination method, and program - Google Patents

Description

The present invention relates to an auxiliary power determining device for determining the power of the plurality of auxiliary machines in a plant having a plurality of auxiliary machines, the plant thereof, an auxiliary power determining method, and a program.

In a power plant, there are a method of improving the efficiency of power generation equipment and a method of reducing auxiliary power as a method of increasing the actual power generation amount. That is, in a power plant, an increase in the actual amount of generated power can be expected by improving the efficiency of auxiliary equipment.
The power plant will be equipped with multiple auxiliary equipment such as cooling tower fans and circulating water pumps. The power of each auxiliary machine can be individually optimized based on the state quantity related to the purpose of the auxiliary machine. For example, the power of the cooling tower fan can be optimized by calculating the required heat dissipation amount based on the turbine load, outside air temperature and outside air humidity. Further, for example, the power of the circulating water pump can be optimized by calculating an appropriate concentration ratio based on the load of the turbine and the water quality of the make-up water.

Patent Document 1 discloses a technique for improving the efficiency of the rotation speed of a cooling tower fan and a cooling water pump in an air conditioning system. Further, Patent Document 2 discloses a technique for controlling the number of heat source units in an air conditioning system.

Japanese Unexamined Patent Publication No. 2008-256258 Japanese Unexamined Patent Publication No. 2012-12649

By operating the auxiliary equipment, various state quantities in the plant change. Therefore, when the power of a certain device is changed, the state quantity used for determining the power of another auxiliary machine may change. For example, when the power of the circulating water pump is changed, the flow velocity of the circulating water changes, and the amount of heat exchange per unit time changes.
Therefore, if each auxiliary machine is optimized based on the individual state quantity, the control of the plurality of auxiliary machines as a whole may not be optimal.
An object of the present invention is to provide an auxiliary power determining device, a plant, an auxiliary power determining method, and a program for optimizing the power of an auxiliary machine in consideration of the state of a plurality of auxiliary machines.

According to a first aspect of the present invention, auxiliary power determination device, it has a plurality of auxiliary devices, to determine the power of the plurality of accessory in the plant comprising the cooling tower for cooling the cooling water complement The maximum concentration factor of the cooling water allowed in the cooling tower based on the state quantity of the plant which is a mobility determining device and affects the first auxiliary machine which is one of the plurality of auxiliary machines. With respect to the maximum concentration ratio specifying unit for calculating the maximum concentration ratio and the plurality of target concentration ratios equal to or less than the maximum concentration ratio, the power of the first auxiliary machine that achieves the target concentration ratio and achieves a predetermined heat exchange amount, and the plurality of A calculation unit that calculates the power of the second auxiliary machine, which is one of the auxiliary machines of the above, and the plurality of target enrichment ratios based on the calculated power of the first auxiliary machine and the second auxiliary machine. It is provided with a determination unit that specifies one of the target enrichment ratios and determines the power of the first auxiliary machine and the second auxiliary equipment based on the specified target enrichment ratio.

According to the second aspect of the present invention, in the auxiliary power determination device according to the first aspect, the determination unit minimizes the total power of the first auxiliary machine and the second auxiliary machine. In addition, it may determine the power.

According to the third aspect of the present invention, in the auxiliary power determination device according to the first aspect, the determination unit corresponds to the selling price of the electric power consumed by the auxiliary machine in the plant and the target enrichment ratio. The power may be determined so as to maximize the difference from the price of water supplied from the water source.

According to the fourth aspect of the present invention, in the auxiliary power determining device according to any one of the first to third aspects, the first auxiliary machine or the second auxiliary machine is the circulating water of the plant. It may be a pump that pumps water from the system.

According to the fifth aspect of the present invention, in the auxiliary machine power determining device according to any one of the first to fourth aspects, the first auxiliary machine or the second auxiliary machine is provided in the plant. It may be a fan of the cooling tower.

According to a sixth aspect of the present invention, the plant has a plurality of auxiliary machines including a first auxiliary machine and a second auxiliary machine, and has a cooling tower for cooling cooling water and the first auxiliary machine. A sensor for measuring a state amount affecting the auxiliary machine and a state amount affecting the second auxiliary machine, and an auxiliary machine power determining device according to any one of the first to fifth aspects are provided.

According to a seventh aspect of the present invention, auxiliary power determination method, it has a plurality of auxiliary devices, to determine the power of the plurality of accessory in the plant comprising the cooling tower for cooling the cooling water complement The maximum concentration ratio of the cooling water allowed in the cooling tower based on the state amount of the plant which is a mobility determination method and affects the first auxiliary machine which is one of the plurality of auxiliary machines. And the power of the first auxiliary machine that achieves the target concentration ratio and achieves a predetermined heat exchange amount with respect to the plurality of target concentration ratios equal to or less than the maximum concentration ratio One of the plurality of target enrichment ratios based on the step of calculating the power of one second auxiliary machine and the calculated power of the first auxiliary machine and the second auxiliary machine. identifying the magnification, and determining a power of the first auxiliary and the second accessory based on the target concentration factor identified.

According to an eighth aspect of the present invention, the program to have a plurality of auxiliary devices, to determine the power of the plurality of accessory in the plant comprising the cooling tower for cooling the cooling water computer, said plurality A step of calculating the maximum concentration ratio of the cooling water allowed in the cooling tower based on the state quantity of the plant affecting the first auxiliary machine, which is one of the auxiliary equipments of the above, and the maximum concentration ratio. With respect to the following plurality of target concentration ratios, the power of the first auxiliary machine that achieves the target concentration ratio and achieves a predetermined heat exchange amount, and the power of the second auxiliary machine that is one of the plurality of auxiliary machines. Based on the step of calculating the power and the calculated power of the first auxiliary machine and the second auxiliary machine, the target enrichment ratio of one of the plurality of target enrichment ratios is specified, and the specified target enrichment ratio is specified. and a step of determining the power of the first auxiliary and the second accessory based on the magnification.

According to at least one of the above aspects, the auxiliary power determining device can optimize the power of the auxiliary machine in consideration of the states of the plurality of auxiliary machines.

It is a schematic block diagram which shows the structure of the power plant which concerns on one Embodiment. It is a schematic block diagram which shows the structure of the auxiliary machine control device which concerns on one Embodiment. It is a figure which shows the example of the relationship between the power of the 3rd water supply pump, and the power of a fan. It is a flowchart which shows the operation of the auxiliary machine control device which concerns on one Embodiment. It is a schematic block diagram which shows the structure of the auxiliary machine control device which concerns on one Embodiment. It is a flowchart which shows the operation of the auxiliary machine control device which concerns on one Embodiment. It is a schematic block diagram which shows the structure of the auxiliary machine control device which concerns on one Embodiment. It is a flowchart which shows the operation of the auxiliary machine control device which concerns on one Embodiment. It is a schematic block diagram which shows the structure of the computer which concerns on at least one Embodiment.

<First Embodiment>
Hereinafter, embodiments will be described in detail with reference to the drawings.

<< Configuration of water treatment system >>
FIG. 1 is a schematic block diagram showing a configuration of a power plant according to an embodiment.
The power plant 10 includes a boiler 11, a steam turbine 12, a generator 13, a condenser 14, a pure water device 15, a cooling tower 16, a steam circulation line 101, a first replenishment line 102, a first drainage line 103, and a first drug. A pouring line 104, a cooling water circulation line 105, a second replenishment line 106, a second drainage line 107, a second chemical pouring line 108, a wastewater treatment device 109, an auxiliary control device 110, an environment measuring device 111, and an operation monitoring device 112 are provided. ..

The boiler 11 evaporates water to generate steam.
The steam turbine 12 is rotated by the steam generated by the boiler 11.
The generator 13 converts the rotational energy of the steam turbine 12 into electric power.
The condenser 14 exchanges heat between the steam discharged from the steam turbine 12 and the cooling water, and returns the steam to water.
The pure water device 15 produces pure water.

The cooling tower 16 cools the cooling water heat-exchanged by the condenser 14. The cooling tower 16 is provided with a fan 161 for promoting evaporation of cooling water and a first power meter 162 for measuring the power consumption of the fan 161. The fan 161 is configured so that the air volume can be adjusted by controlling the number of fans or controlling the inverter. The first power meter 162 transmits fan power, which is the measured power consumption, to the auxiliary control device 110.

The steam circulation line 101 is a line for circulating water and steam to the steam turbine 12, the condenser 14, and the boiler 11. A first water supply pump 1011 is provided between the condenser 14 and the boiler 11 in the steam circulation line 101. The first water supply pump 1011 pumps water from the condenser 14 to the boiler 11.

The first replenishment line 102 is a line for supplying the pure water generated by the pure water device 15 to the steam circulation line 101. A second water supply pump 1021 is provided on the first supply line 102. The second water supply pump 1021 is used when the condenser 14 is filled with water. During operation, the water in the first replenishment line 102 is pumped from the pure water device 15 toward the condenser 14 by the depressurization of the condenser 14.

The first drainage line 103 is a line for discharging a part of the water circulating in the steam circulation line 101 from the boiler 11 to the wastewater treatment device 109.
The first chemical injection line 104 is a line for supplying chemicals such as an anticorrosive agent, an antiscale agent, and a slime control agent to the vapor circulation line 101. The first drug injection line 104 includes a first drug tank 1041 for storing the drug and a first drug injection pump 1042 for supplying the drug from the first drug tank 1041 to the vapor circulation line 101.

The cooling water circulation line 105 is a line for circulating cooling water to the condenser 14 and the cooling tower 16. The cooling water circulation line 105 is provided with a third water supply pump 1051, a cooling water quality sensor 1052, a circulating water amount sensor 1053, a cooling tower inlet water temperature sensor 1054, a cooling tower outlet water temperature sensor 1055, and a second power meter 1056. The third water supply pump 1051 pumps cooling water from the cooling tower 16 toward the condenser 14.
The cooling water quality sensor 1052 detects the water quality of the cooling water circulating in the cooling water circulation line 105. Examples of water quality detected by the sensor include electrical conductivity, pH value, salt concentration, metal concentration, COD (Chemical Oxygen Demand), BOD (Biochemical Oxygen Demand), microbial concentration, and silica concentration, and combinations thereof. Can be mentioned. The cooling water quality sensor 1052 outputs a circulating water quality index value indicating the detected water quality to the auxiliary control device 110. The circulating water amount sensor 1053 detects the flow rate of the cooling water circulating in the cooling water circulation line 105. The circulating water amount sensor 1053 outputs the circulating water amount indicating the detected water amount to the auxiliary control device 110. The cooling tower inlet water temperature sensor 1054 detects the temperature of the cooling water circulating in the cooling water circulation line 105. The cooling tower inlet water temperature sensor 1054 outputs the circulating water temperature indicating the detected temperature to the auxiliary control device 110. The second power meter 1056 measures the power consumption of the third water supply pump 1051. The second power meter 1056 outputs the pump power indicating the measured power consumption to the auxiliary control device 110.

The second replenishment line 106 is a line for supplying the raw water taken from the water source to the cooling water circulation line 105 as replenishment water. The second replenishment line 106 is provided with a fourth water supply pump 1061 and a replenishment water quality sensor 1062. The fourth water supply pump 1061 pumps make-up water from the water source toward the cooling tower 16. The make-up water quality sensor 1062 outputs a make-up water quality index value indicating the detected water quality to the auxiliary control device 110.
The second drainage line 107 is a line for discharging a part of the water circulating in the cooling water circulation line 105 to the wastewater treatment device 109. The second drainage line 107 is provided with a blow valve 1071 and a drainage quality sensor 1072. The blow valve 1071 limits the amount of wastewater blown from the cooling water circulation line 105 to the wastewater treatment device 109.

The second drug injection line 108 is a line for supplying a drug to the cooling water circulation line 105. The second drug injection line 108 includes a second drug tank 1081 for storing the drug and a second drug injection pump 1082 for supplying the drug from the second drug tank 1081 to the cooling water circulation line 105.

The wastewater treatment device 109 injects an acid, an alkali, a coagulant, or other chemicals into the wastewater discharged from the first wastewater line 103 and the second wastewater line 107. The wastewater treatment device 109 discards the wastewater treated by the chemicals.

The auxiliary control device 110 includes the fan power detected by the first power meter 162, the cooling water quality index value detected by the cooling water quality sensor 1052, the make-up water quality index value detected by the make-up water quality sensor 1062, and the circulation detected by the circulating water amount sensor 1053. Amount of water, cooling tower inlet water temperature detected by cooling tower inlet water temperature sensor 1054, cooling tower outlet water temperature detected by cooling tower outlet water temperature sensor 1055, pump power detected by second power meter 1056, wet bulb measured by environment measuring device 111 The power of the fan 161 and the power of the third water supply pump 1051 are determined based on the temperature and the generated power measured by the operation monitoring device 112. The fan 161 and the third water supply pump 1051 are examples of auxiliary equipment.

The environment measuring device 111 measures the wet-bulb temperature in the vicinity of the cooling tower 16.
The operation monitoring device 112 measures the generated power of the power plant 10.

<< Relationship between the state quantity of the power plant and auxiliary equipment >>
The fan 161 promotes the evaporation of water in the cooling tower 16. Therefore, it is necessary to increase the power of the fan 161 so that the water does not easily evaporate in the cooling tower 16. The amount of water evaporation changes depending on the wet-bulb temperature of the atmosphere. That is, the wet-bulb temperature in the vicinity of the cooling tower 16 is an example of a state quantity that affects the fan 161.
The third water supply pump 1051 controls the circulation amount of the cooling water in the cooling water circulation line 105. It is necessary to keep the quality of the cooling water above a certain level in order to prevent the cooling water circulation line 105 from being damaged by corrosion, scaling, fouling and the like, and to reduce the environmental load caused by the blow water. That is, the cooling water quality index value and the make-up water quality index value are examples of the state quantities that affect the third water supply pump 1051. Further, the higher the generated power of the power plant 10, the larger the amount of heat exchange in the condenser 14, it is necessary to increase the operating amount of the third water supply pump 1051. That is, the generated power of the power plant 10 is an example of a state quantity that affects the third water supply pump 1051.

If the quality of the cooling water is good, it may be possible to keep the water quality above a certain level even if the circulation multiple is increased. In this case, if an increase in the circulation multiple is allowed, the power of the third water supply pump 1051 can be reduced. On the other hand, when the power of the third water supply pump 1051 decreases, the flow velocity of the cooling water exchanged by the cooling tower 16 decreases, so that the amount of heat exchange may decrease. As a result, the amount of heat released by the cooling tower 16 is reduced, so it is necessary to increase the power of the fan 161.

<< Configuration of auxiliary control device >>
FIG. 2 is a schematic block diagram showing a configuration of an auxiliary equipment control device according to an embodiment.
The auxiliary control device 110 includes an information acquisition unit 1101, a maximum concentration ratio specifying unit 1102, a pump power calculation unit 1103, an inlet water temperature estimation unit 1104, a fan power calculation unit 1105, a determination unit 1106, and an output unit 1107.

The information acquisition unit 1101 has a fan power detected by the first power meter 162, a cooling water quality index value detected by the cooling water quality sensor 1052, a make-up water quality index value detected by the make-up water quality sensor 1062, and a circulating water amount detected by the circulating water amount sensor 1053. , Cooling tower inlet water temperature detected by cooling tower inlet water temperature sensor 1054, cooling tower outlet water temperature detected by cooling tower outlet water temperature sensor 1055, pump power detected by second power meter 1056, wet bulb temperature measured by environment measuring device 111. , Acquires the generated power measured by the operation monitoring device 112.

The maximum concentration ratio specifying unit 1102 specifies the maximum concentration ratio allowed in the cooling water circulation line 105 based on the cooling water quality index value, the make-up water quality index value, and the generated power acquired by the information acquisition unit 1101. The maximum enrichment ratio specifying unit 1102 may specify, for example, the maximum enrichment ratio based on a table associated with the cooling water quality index value, the make-up water quality index value, the generated power, and the maximum enrichment ratio. Then, the cooling water quality after a certain period of time may be estimated from the cooling water quality index value, the make-up water quality index value, and the generated power, and the maximum concentration ratio may be specified based on the cooling water quality after a certain period of time. The maximum concentration ratio becomes higher as the cooling water quality index value is lower (the better the water quality).

The pump power calculation unit 1103 calculates the power of the third water supply pump 1051 when a plurality of concentration ratios equal to or less than the maximum concentration ratio specified by the maximum concentration ratio specifying unit 1102 are set as the target concentration ratio. Once the target concentration ratio is determined, the pump power calculation unit 1103 can calculate the blow water amount and the circulation flow rate corresponding to the target concentration ratio. The blow water amount and the circulation flow rate become lower as the target concentration ratio is higher.

The inlet water temperature estimation unit 1104 estimates the cooling tower inlet water temperature after a certain period of time based on the cooling tower outlet water temperature and the generated power acquired by the information acquisition unit 1101. The larger the generated power, the greater the amount of heat exchange in the condenser 14. Therefore, the water temperature at the inlet of the cooling tower increases as the generated power increases. Further, the water temperature at the inlet of the cooling tower becomes higher as the water temperature at the outlet of the cooling tower is higher.

The fan power calculation unit 1105 includes the cooling tower inlet water temperature estimated by the inlet water temperature estimation unit 1104 after a certain period of time, the wet-bulb temperature of the atmosphere acquired by the information acquisition unit 1101, and the circulation flow rate calculated by the pump power calculation unit 1103. Based on, the power of the fan 161 for each target enrichment ratio is calculated. The power of the fan 161 is higher as the wet-bulb temperature is higher, higher as the water temperature at the inlet of the cooling tower is higher, and lower as the amount of circulating water is larger.

FIG. 3 is a diagram showing an example of the relationship between the power of the third water supply pump and the power of the fan.
A plurality of determination units 1106 are based on the power of the third water supply pump 1051 for each target enrichment ratio calculated by the pump power calculation unit 1103 and the power of the fan 161 for each target enrichment ratio calculated by the fan power calculation unit 1105. Among the target concentration ratios of the above, the one that minimizes the sum of the power of the third water supply pump 1051 and the power of the fan 161 is specified. The determination unit 1106 determines the power of the third water supply pump 1051 and the power of the fan 161 related to the specified target concentration ratio as the power of the third water supply pump 1051 and the power of the fan 161.
As shown in FIG. 3, there is a trade-off relationship between the power of the third water supply pump 1051 and the power of the fan 161. In the example of FIG. 3, in the determination unit 1106, the target concentration ratio related to the intersection of the line indicating the power of the third water supply pump 1051 and the line indicating the power of the fan 161 is set to the power of the third water supply pump 1051 and the fan 161. The total power of is minimized. As shown in FIG. 3, since each target enrichment ratio is a value equal to or less than the maximum enrichment ratio calculated by the maximum enrichment ratio specifying unit 1102, the determination unit 1106 determines the power related to any of the plurality of target enrichment ratios. By using, the quality of the cooling water can be kept above a certain level.

The output unit 1107 outputs an instruction to the third water supply pump 1051 and the fan 161 to operate with the power determined by the determination unit 1106.

<< Operation of auxiliary control device >>
FIG. 4 is a flowchart showing the operation of the auxiliary equipment control device according to the embodiment.
The information acquisition unit 1101 has a fan power detected by the first power meter 162, a cooling water quality index value detected by the cooling water quality sensor 1052, a make-up water quality index value detected by the make-up water quality sensor 1062, and a circulating water amount detected by the circulating water amount sensor 1053. , Cooling tower inlet water temperature detected by cooling tower inlet water temperature sensor 1054, cooling tower outlet water temperature detected by cooling tower outlet water temperature sensor 1055, pump power detected by second power meter 1056, wet bulb temperature measured by environment measuring device 111. , Acquire the generated power measured by the operation monitoring device 112 (step S11).

Next, the maximum concentration ratio specifying unit 1102 specifies the maximum concentration ratio allowed in the cooling water circulation line 105 based on the cooling water quality index value, the make-up water quality index value, and the generated power acquired by the information acquisition unit 1101. (Step S12). The pump power calculation unit 1103 calculates the power of the third water supply pump 1051 when a plurality of concentration ratios equal to or less than the maximum concentration ratio specified by the maximum concentration ratio specifying unit 1102 are set as the target concentration ratio (step S13).

The inlet water temperature estimation unit 1104 estimates the cooling tower inlet water temperature after a certain period of time based on the cooling tower outlet water temperature and the generated power acquired by the information acquisition unit 1101 (step S14). The fan power calculation unit 1105 includes the cooling tower inlet water temperature estimated by the inlet water temperature estimation unit 1104 after a certain period of time, the wet-bulb temperature of the atmosphere acquired by the information acquisition unit 1101, and the circulation flow rate calculated by the pump power calculation unit 1103. Based on the above, the power of the fan 161 for each target enrichment ratio is calculated (step S15). It should be noted that calculating the power of the fan 161 based on the power of the third water supply pump 1051 determined based on the cooling water quality index value, the make-up water quality index value, and the generated power is the cooling water quality index value and the make-up water quality index value. , And determining the power of the fan 161 based on the generated power.

The determination unit 1106 identifies the one in which the total of the power of the third water supply pump 1051 and the power of the fan 161 is the smallest among the plurality of target concentration ratios equal to or less than the maximum concentration ratio, and the third water supply related to the target concentration ratio. The power of the pump 1051 and the power of the fan 161 are determined as the power of the third water supply pump 1051 and the power of the fan 161 (step S16). The output unit 1107 outputs an instruction to the third water supply pump 1051 and the fan 161 to operate with the power determined by the determination unit 1106 (step S17). As a result, the third water supply pump 1051 and the fan 161 can be operated with a small power while keeping the water quality in the cooling water circulation line 105 above a certain level.

《Action / Effect》
As described above, according to the first embodiment, the auxiliary equipment control device 110 is a cooling water quality index value which is a state quantity of the power plant 10 affecting the third water supply pump 1051 which is one of the plurality of auxiliary equipment. , The power of the fan 161 which is one of the plurality of auxiliary machines is determined based on the make-up water quality index value and the generated power. As a result, the auxiliary control device 110 can determine the power of the fan 161 according to the water quality in the cooling water circulation line 105.

Further, according to the first embodiment, the auxiliary control device 110 determines the power so that the total power of the third water supply pump 1051 and the fan 161 is minimized. As a result, the power consumption by the auxiliary equipment of the plant can be reduced and the actual power generation can be increased.

The power of the third water supply pump 1051 which is a pump for pumping water from the circulating water system of the power generation plant 10 and the power of the fan 161 of the cooling tower 16 occupy most of the total power of the auxiliary machinery in the entire power generation plant 10. Therefore, by minimizing the total value of the power of the third water supply pump 1051 and the power of the fan 161 of the cooling tower 16, the power consumption of the entire power plant 10 can be significantly reduced.

<Second embodiment>
The auxiliary control device 110 according to the first embodiment determines the power of the third water supply pump 1051 and the fan 161 so that the total power is minimized. On the other hand, depending on the price of water obtained from the water source and the selling price of electricity, it may be cheaper to increase or decrease the amount of blown water and the power of the third water supply pump 1051.
In view of this, the auxiliary equipment control device 110 according to the second embodiment determines the power of the auxiliary equipment so that the actual power generated by the plant is maximized.

<< Configuration of auxiliary control device >>
FIG. 5 is a schematic block diagram showing a configuration of an auxiliary equipment control device according to an embodiment.
The auxiliary control device 110 according to the second embodiment further includes a price storage unit 1108 and a blow water amount calculation unit 1109 in addition to the configuration according to the first embodiment.
The price storage unit 1108 stores the price per unit amount of water obtained from the water source and the selling price per unit electric power.
The blow water amount calculation unit 1109 calculates the amount of water to be drained from the second drain line 107 (blow water amount) when a plurality of concentration ratios equal to or less than the maximum concentration ratio specified by the maximum concentration ratio specifying unit 1102 are set as the target concentration ratio. .. The higher the target concentration ratio, the lower the blow water amount.

The determination unit 1106 according to the second embodiment has a third power based on the power of the third water supply pump 1051 and the fan 161 for each target enrichment ratio and the selling price per unit electric power stored in the price storage unit 1108. The selling price of the electric power consumed by the operation of the water supply pump 1051 and the fan 161 is calculated. Further, the determination unit 1106 calculates the price of water acquired from the water source based on the amount of blown water for each target concentration ratio and the price per unit amount of water stored in the price storage unit 1108. The determination unit 1106 identifies, among the plurality of target enrichment ratios, the one that minimizes the sum of the selling price of the consumed electricity and the price of water obtained from the water source. The determination unit 1106 determines the power of the third water supply pump 1051 and the power of the fan 161 related to the specified target concentration ratio as the power of the third water supply pump 1051 and the power of the fan 161.

<< Operation of auxiliary control device >>
FIG. 6 is a flowchart showing the operation of the auxiliary equipment control device according to the embodiment.
The information acquisition unit 1101 has a fan power detected by the first power meter 162, a cooling water quality index value detected by the cooling water quality sensor 1052, a make-up water quality index value detected by the make-up water quality sensor 1062, and a circulating water amount detected by the circulating water amount sensor 1053. , Cooling tower inlet water temperature detected by cooling tower inlet water temperature sensor 1054, cooling tower outlet water temperature detected by cooling tower outlet water temperature sensor 1055, pump power detected by second power meter 1056, wet bulb temperature measured by environment measuring device 111. , Acquire the generated power measured by the operation monitoring device 112 (step S21).

Next, the maximum concentration ratio specifying unit 1102 specifies the maximum concentration ratio allowed in the cooling water circulation line 105 based on the cooling water quality index value, the make-up water quality index value, and the generated power acquired by the information acquisition unit 1101. (Step S22). The pump power calculation unit 1103 calculates the power of the third water supply pump 1051 when a plurality of concentration ratios equal to or less than the maximum concentration ratio specified by the maximum concentration ratio specifying unit 1102 are set as the target concentration ratio (step S23). Further, the blow water amount calculation unit 1109 calculates the amount of blow water from the second drainage line 107 when a plurality of concentration ratios equal to or less than the maximum concentration ratio specified by the maximum concentration ratio specifying unit 1102 are set as the target concentration ratio (step). S24).

The inlet water temperature estimation unit 1104 estimates the cooling tower inlet water temperature after a certain period of time based on the cooling tower outlet water temperature and the generated power acquired by the information acquisition unit 1101 (step S25). The fan power calculation unit 1105 includes the cooling tower inlet water temperature estimated by the inlet water temperature estimation unit 1104 after a certain period of time, the wet-bulb temperature of the atmosphere acquired by the information acquisition unit 1101, and the circulation flow rate calculated by the pump power calculation unit 1103. Based on the above, the power of the fan 161 for each target enrichment ratio is calculated (step S26).

Based on the information stored in the price storage unit 1108, the determination unit 1106 determines the selling price of the power consumed by the third water supply pump 1051 related to each target enrichment ratio and the power consumed by the fan 161 related to each target enrichment ratio. The selling price and the price of water supplied from the water source related to each target concentration ratio are calculated (step S27). The determination unit 1106 identifies the one that minimizes the sum of the selling price of electric power and the price of water, and sets the power of the third water supply pump 1051 and the power of the fan 161 related to the target concentration ratio to the third water supply pump. The power of 1051 and the power of fan 161 are determined (step S28). The output unit 1107 outputs an instruction to the third water supply pump 1051 and the fan 161 to operate with the power determined by the determination unit 1106 (step S29). As a result, the third water supply pump 1051 and the fan 161 can be operated so as to reduce the expenditure while keeping the water quality in the cooling water circulation line 105 above a certain level.

《Action / Effect》
As described above, according to the second embodiment, the auxiliary control device 110 minimizes the sum of the power selling price of the third water supply pump 1051 and the fan 161 and the price of the make-up water from the water source. So, determine the power. As a result, the auxiliary equipment control device 110 can reduce the expenditure by the auxiliary equipment and increase the actual selling price of electricity.

<Third embodiment>
It is known that the characteristics of the power plant 10 change due to deterioration or the like. Therefore, the auxiliary equipment control device 110 according to the third embodiment determines an appropriate auxiliary equipment power according to the change of the power generation plant 10 by machine learning or simulation based on the state of the power generation plant 10.

<< Configuration of auxiliary control device >>
FIG. 7 is a schematic block diagram showing the configuration of the auxiliary equipment control device according to the embodiment.
The auxiliary machine control device 110 includes an information acquisition unit 1101, a model storage unit 1110, a maximum concentration magnification identification unit 1111, a power identification unit 1112, a price storage unit 1108, a determination unit 1106, an output unit 1107, an input unit 1113, and an update unit 1114. Be prepared.

The model storage unit 1110 uses the information acquired by the information acquisition unit 1101 as an input to output the maximum enrichment ratio model, and the information acquired by the information acquisition unit 1101 and the target enrichment ratio as inputs to the third water supply pump. The power of 1051 and fan 161 and the power model for outputting the blow water amount are stored. The enrichment factor model and the power model are machine learning models such as neural network models, or simulation models.

The maximum enrichment ratio specifying unit 1111 specifies the maximum enrichment ratio by inputting the information acquired by the information acquisition unit 1101 into the enrichment ratio model stored in the model storage unit 1110.
The power specifying unit 1112 specifies a plurality of target enrichment ratios equal to or less than the maximum enrichment ratio specified by the maximum enrichment ratio specifying unit 1111. The power specifying unit 1112 specifies the power of the third water supply pump 1051 and the fan 161 and the blow water amount related to each target concentration ratio based on the power model stored in the model storage unit 1110. That is, the power specifying unit 1112 identifies the power of the fan 161 based on the state amount affecting the third water supply pump 1051 acquired by the information acquisition unit 1101, and the power specifying unit 1112 identifies the power of the fan 161 based on the state amount affecting the fan 161. 3 Identify the power of the water supply pump 1051.

The input unit 1113 receives the power input of the third water supply pump 1051 and the fan 161 from the user.
The update unit 1114 updates the model stored in the model storage unit 1110 based on the information acquired by the information acquisition unit 1101 and the information input to the input unit 1113. For example, the update unit 1114 can specify the relationship between the information acquired by the information acquisition unit 1101 and the enrichment ratio from the information acquired by the information acquisition unit 1101. Specifically, since the concentration ratio can be calculated from the amount of circulating water acquired by the information acquisition unit 1101, the update unit 1114 concentrates using the combination of the information acquired by the information acquisition unit 1101 and the concentration ratio. The magnification model can be updated.
Further, for example, the update unit 1114 specifies the relationship between the information acquired by the information acquisition unit 1101 and the power of the fan 161, the power of the third water supply pump 1051, and the blow water amount from the information acquired by the information acquisition unit 1101. be able to. Specifically, the blow water amount can be calculated from the circulating water amount acquired by the information acquisition unit 1101, and the power of the fan 161 and the power of the third water supply pump 1051 can be calculated from the fan power and the pump power, respectively. Therefore, the update unit 1114 can update the power model using the combination of the information acquired by the information acquisition unit 1101, the power of the fan 161 and the third water supply pump 1051 and the blow water amount as teacher data.
Further, for example, the update unit 1114 can update the power model based on the information acquired by the information acquisition unit 1101, the power of the fan 161 input to the input unit 1113, and the power of the third water supply pump 1051. ..

<< Operation of auxiliary control device >>
FIG. 8 is a flowchart showing the operation of the auxiliary equipment control device according to the embodiment.
The information acquisition unit 1101 has a fan power detected by the first power meter 162, a cooling water quality index value detected by the cooling water quality sensor 1052, a make-up water quality index value detected by the make-up water quality sensor 1062, and a circulating water amount detected by the circulating water amount sensor 1053. , Cooling tower inlet water temperature detected by cooling tower inlet water temperature sensor 1054, cooling tower outlet water temperature detected by cooling tower outlet water temperature sensor 1055, pump power detected by second power meter 1056, wet bulb temperature measured by environment measuring device 111. , Acquire the generated power measured by the operation monitoring device 112 (step S31).

Next, the maximum enrichment ratio specifying unit 1111 specifies the maximum enrichment ratio by inputting the information acquired by the information acquisition unit 1101 into the enrichment ratio model stored in the model storage unit 1110 (step S32). Next, the power specifying unit 1112 specifies a plurality of concentration ratios equal to or less than the maximum concentration ratio specified by the maximum concentration ratio specifying unit 1102 as the target concentration ratio (step S33). Next, the power specifying unit 1112 inputs the information acquired by the information acquisition unit 1101 and the target enrichment ratio into the power model stored in the model storage unit 1110 for each specified target enrichment ratio, thereby causing the third water supply pump. The power of 1051 and fan 161 and the amount of blow water are specified (step S34).

Based on the information stored in the price storage unit 1108, the determination unit 1106 determines the selling price of the power consumed by the third water supply pump 1051 related to each target enrichment ratio and the power consumed by the fan 161 related to each target enrichment ratio. The selling price and the price of water supplied from the water source related to each target concentration ratio are calculated (step S35). The determination unit 1106 identifies the one that minimizes the sum of the selling price of electric power and the price of water, and sets the power of the third water supply pump 1051 and the power of the fan 161 related to the target concentration ratio to the third water supply pump. The power of 1051 and the power of fan 161 are determined (step S36). The output unit 1107 outputs an instruction to the third water supply pump 1051 and the fan 161 to operate with the power determined by the determination unit 1106 (step S37). As a result, the third water supply pump 1051 and the fan 161 can be operated so as to reduce the expenditure while keeping the water quality in the cooling water circulation line 105 above a certain level.

《Action / Effect》
As described above, according to the third embodiment, when the characteristics of the auxiliary control device 110 change due to deterioration of the power plant 10 or the like due to the update of the enrichment ratio model and the power model by the update unit 1114. Also, the power of the auxiliary equipment can be determined appropriately.

Although one embodiment has been described in detail with reference to the drawings, the specific configuration is not limited to the above, and various design changes and the like can be made.
For example, in the above embodiment, the auxiliary control device 110 determines the power of the fan 161 and the third water supply pump 1051, but is not limited to this. For example, in other embodiments, the power of other accessories such as the fan 161 and the third water supply pump 1051 may be added to or replaced by the first water supply pump 1011.

Further, in the above-described embodiment, the auxiliary machine control device 110 for controlling the auxiliary machine has been described as an example of the auxiliary machine power determination device, but the present invention is not limited to this. For example, in another embodiment, the power plant 10 may include an auxiliary power determining device that displays the calculated power on a display or the like without directly controlling the auxiliary equipment, instead of the auxiliary equipment control device 110. .. In this case, the operator visually recognizes the output value and controls the auxiliary machine.

<Computer configuration>
FIG. 9 is a schematic block diagram showing a configuration of a computer according to at least one embodiment.
The computer 900 includes a CPU 902, a main storage device 902, an auxiliary storage device 903, and an interface 904.
The auxiliary control device 110 described above is mounted on the computer 900. The operation of each processing unit described above is stored in the auxiliary storage device 903 in the form of a program. The CPU 902 reads the program from the auxiliary storage device 903, expands it to the main storage device 902, and executes the above processing according to the program. Further, the CPU 902 secures a storage area corresponding to each of the above-mentioned storage units in the main storage device 902 or the auxiliary storage device 903 according to the program.

Examples of the auxiliary storage device 903 include HDD (Hard Disk Drive), SSD (Solid State Drive), magnetic disk, optical magnetic disk, CD-ROM (Compact Disc Read Only Memory), and DVD-ROM (Digital Versatile Disc Read Only). Memory), semiconductor memory and the like. The auxiliary storage device 903 may be internal media directly connected to the bus of computer 900, or external media connected to computer 900 via interface 904 or a communication line. When this program is distributed to the computer 900 via a communication line, the distributed computer 900 may expand the program to the main storage device 902 and execute the above processing. In at least one embodiment, the auxiliary storage device 903 is a non-temporary tangible storage medium.

Further, the program may be for realizing a part of the above-mentioned functions. Further, the program may be a so-called difference file (difference program) that realizes the above-mentioned function in combination with another program already stored in the auxiliary storage device 903.

10 Power plant 16 Cooling tower 161 Fan 162 1st power meter 105 Cooling water circulation line 1051 3rd water supply pump 1052 Cooling water quality sensor 1053 Circulating water amount sensor 1054 Cooling tower inlet water temperature sensor 1055 Cooling tower outlet water temperature sensor 1056 2nd power meter 110 Auxiliary equipment Control device 1101 Information acquisition unit 1102 Maximum concentration magnification identification unit 1103 Pump power calculation unit 1104 Inlet water temperature estimation unit 1105 Fan power calculation unit 1106 Determination unit 1107 Output unit 1108 Price storage unit 1109 Blow water amount calculation unit 1110 Model storage unit 1111 Maximum concentration ratio Specific unit 1112 Power specific unit 1113 Input unit 1114 Update unit 111 Environmental measurement device 112 Operation monitoring device

Claims (8)

Have a plurality of auxiliary devices, a auxiliary power determination device for determining the power of said plurality of auxiliary devices in the plant comprising the cooling tower for cooling the cooling water,
Maximum concentration factor specifying unit that calculates the maximum concentration factor of the cooling water allowed in the cooling tower based on the state quantity of the plant affecting the first auxiliary machine which is one of the plurality of auxiliary machines. When,
For a plurality of target concentration ratios equal to or lower than the maximum concentration ratio, the power of the first auxiliary machine that achieves the target concentration ratio and achieves a predetermined heat exchange amount, and the second auxiliary machine that is one of the plurality of auxiliary machines. And the calculation unit that calculates the power of the auxiliary machine
The target enrichment ratio of one of the plurality of target enrichment ratios is specified based on the calculated power of the first auxiliary machine and the second auxiliary equipment, and the first enrichment ratio is based on the specified target enrichment ratio. auxiliary power determination device and a determining section for determining the auxiliary and power of the second accessory. The auxiliary power determination device according to claim 1, wherein the determination unit determines the power so that the total power of the first auxiliary machine and the second auxiliary machine is minimized. The determination unit determines the power so that the difference between the selling price of the electric power consumed by the auxiliary machine of the plant and the price of water supplied from the water source according to the target concentration ratio is maximized. The auxiliary power determination device according to claim 1. The auxiliary power determining device according to any one of claims 1 to 3, wherein the first auxiliary machine or the second auxiliary machine is a pump for pumping water from the circulating water system of the plant. The auxiliary power determining device according to any one of claims 1 to 4, wherein the first auxiliary machine or the second auxiliary machine is a fan of a cooling tower provided in the plant. A cooling tower having a plurality of auxiliary machines including a first auxiliary machine and a second auxiliary machine for cooling cooling water,
A sensor that measures the amount of state that affects the first auxiliary machine and the amount of state that affects the second auxiliary machine,
A plant including the auxiliary power determining device according to any one of claims 1 to 5. Have a plurality of auxiliary devices, a auxiliary power determination method for determining the power of said plurality of auxiliary equipment in the plant comprising the cooling tower for cooling the cooling water,
A step of calculating the maximum concentration ratio of the cooling water allowed in the cooling tower based on the state quantity of the plant affecting the first auxiliary machine which is one of the plurality of auxiliary machines.
For a plurality of target concentration ratios equal to or lower than the maximum concentration ratio, the power of the first auxiliary machine that achieves the target concentration ratio and achieves a predetermined heat exchange amount, and the second auxiliary machine that is one of the plurality of auxiliary machines. Steps to calculate the power of auxiliary equipment and
The target enrichment ratio of one of the plurality of target enrichment ratios is specified based on the calculated power of the first auxiliary machine and the second auxiliary equipment, and the first enrichment ratio is based on the specified target enrichment ratio. auxiliary power determination method and a step of the auxiliary and determining power of the second accessory. To have a plurality of auxiliary devices, to determine the power of the plurality of accessory in the plant comprising the cooling tower for cooling the cooling water computer,
A step of calculating the maximum concentration ratio of the cooling water allowed in the cooling tower based on the state quantity of the plant affecting the first auxiliary machine which is one of the plurality of auxiliary machines.
For a plurality of target concentration ratios equal to or lower than the maximum concentration ratio, the power of the first auxiliary machine that achieves the target concentration ratio and achieves a predetermined heat exchange amount, and the second auxiliary machine that is one of the plurality of auxiliary machines. Steps to calculate the power of auxiliary equipment and
The target enrichment ratio of one of the plurality of target enrichment ratios is specified based on the calculated power of the first auxiliary machine and the second auxiliary equipment, and the first enrichment ratio is based on the specified target enrichment ratio. program for executing the steps of determining the power of the auxiliary and the second auxiliary machine.

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