JP2011110441A - System for controlling operation of desulfurization equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To economically carry out the operation according to the market prices of relevant items. <P>SOLUTION: A system for controlling the operation of a desulfurization apparatus equipped with an absorption column for bringing an exhaust gas into contact with an absorbing liquid so as to allow the absorbing liquid to absorb SO<SB>2</SB>in the exhaust gas while discharging the desulfurized exhaust gas from which SO<SB>2</SB>has been removed, is provided with a management unit for, while regulating the amount of SO<SB>2</SB>removed from the exhaust gas within a definite range, setting the feeding rate of the absorbing liquid to the absorption column and the feeding rate of a material constituting the absorbing liquid in such a manner that an evaluation index E, which is calculated by subtracting the income market price of income items arising from the operation of the desulfurization apparatus from the expenditure market price of expenditure items arising from the operation of the desulfurization apparatus, is minimized. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to an operation control system for a desulfurization facility that removes SO ₂ contained in exhaust gas.

  Conventionally, Patent Document 1 discloses a control device that controls a plurality of environmental devices installed to remove a predetermined substance with respect to one exhaust gas system in which the concentration of the predetermined substance contained in the exhaust gas is managed. An environmental device control system including a measuring device that detects a concentration of a predetermined substance is disclosed. In this environmental device control system, the control device stores an efficiency table including efficiency information of a predetermined element with respect to a predetermined substance removal capability for each of a plurality of environmental devices, and the measurement unit calculates the detected concentration of the predetermined substance. The control device determines the amount of change for changing the concentration of the substance from the concentration of the predetermined substance received from the measurement unit and the target value of the concentration of the predetermined substance. Then, an efficient environmental device is selected with reference to the efficiency table, and control is performed so that the environmental device performs processing. According to this control system, the apparatus can be efficiently operated, and energy saving or low operation cost can be achieved.

JP 2004-37056 A

By the way, in recent years, the trading market for SO ₂ emission rights has become active. For this reason, not only an operation that achieves the SO ₂ emission regulation value but also an economical operation that responds to fluctuations in the SO ₂ emission right is desired. For example, when the market price of SO ₂ emission rights falls, the excess is sold in the market by removing SO ₂ more than the emission regulation value, and conversely when the market price of SO ₂ emission rights rises Can operate above the emission limit and purchase the shortage. Furthermore, in addition to the SO ₂ emission rights, for example, the absorbing liquid that absorbs SO ₂ , and the power charges for operating the pump, etc., change the market price over time, so the optimal conditions for economic operation always fluctuate.

  This invention solves the subject mentioned above, and it aims at providing the operation control system of the desulfurization installation which can perform the economical driving | operation according to the market price of various things.

To achieve the above object, in desulfurization operation control system of the present invention, while absorbing the SO ₂ in the flue gas by contacting the absorption liquid to the exhaust gas in the absorption liquid SO ₂ has been removed desulfurized In the operation control system of a desulfurization facility provided with an absorption tower for discharging exhaust gas, from the expenditure market price of various expenditures generated in accordance with the operation of the desulfurization facility while the SO ₂ removal amount obtained by removing SO ₂ from the exhaust gas is within a predetermined range In a mode in which the evaluation index obtained by subtracting the revenue market price of revenues generated in accordance with the operation of the desulfurization facility is minimized, the amount of the absorption liquid sent to the absorption tower and the supply amount of the material constituting the absorption liquid are set. A management device is provided.

According to this operation control system for desulfurization equipment, when the revenue market price is high, the SO ₂ removal amount is increased, and conversely, when the income market price is low, control is performed so as to reduce the operation cost of the desulfurization equipment. In this way, it becomes possible to optimize the operating conditions of the desulfurization equipment according to the revenue market price. As a result, the desulfurization equipment always uses exhaust gas conditions and SO ₂ sales that change from moment to moment, and various unit prices (for example, unit price of electric power, unit price of absorbent material, unit price of water supply, unit price of fuel) that change relatively slowly. It is possible to perform an economical operation that minimizes the cost caused by the operation of the vehicle. In addition, depending on the conditions, the revenue market price is higher than the expenditure market price, so it is also possible to record profits by operating the desulfurization facility.

  Further, in the operation control system for a desulfurization facility of the present invention, the management device has a predictive evaluation index obtained by subtracting the revenue market price from the expenditure market price for the predetermined period in the past in the absorption tower. The amount of the absorbing liquid to be sent and the supply amount of the material constituting the absorbing liquid are set in advance.

According to the operation control system of the desulfurization facility, when the past revenue market price is high, the SO ₂ removal amount is increased, and conversely, when the past revenue market price is low, the desulfurization facility operation cost is reduced. Set to. In this way, it is possible to predict the optimum operating conditions of the desulfurization facility according to the past revenue market price. As a result, the manager of the facility can make a prior arrangement for materials such as utilities by planning in advance.

Further, in desulfurization operation control system of the present invention, SO ₂ concentration in the flue gas, and acquires the SO ₂ concentration in the desulfurized flue gas, delivery of the absorbing liquid to the absorption tower, and the absorbing solution SO _{2 in} the exhaust gas by a control device that controls the supply of the material to be formed, the absorption tower, the absorption liquid delivery section that sends the absorption liquid to the absorption tower, and the material supply section that supplies the material that forms the absorption liquid. The desulfurization equipment which removes is comprised, The said management apparatus is connected to the said control apparatus in the said desulfurization equipment via a network so that communication is possible.

  According to the operation control system for the desulfurization facility, the operation control of the desulfurization facility can be performed remotely via the network.

  In the operation control system for a desulfurization facility according to the present invention, the management device is connected to the control devices in a plurality of the desulfurization facilities via a network.

  According to the operation control system for the desulfurization facility, it is possible to perform operation control of a plurality of desulfurization facilities in a remote place through a network.

  According to the present invention, it is possible to perform economical operation according to the market price of various things.

FIG. 1 is a schematic diagram of an operation control system for a desulfurization facility according to Embodiment 1 of the present invention. FIG. 2 is a block diagram of the operation control system for the desulfurization facility according to Embodiment 1 of the present invention. FIG. 3 is a flowchart showing the operation of the operation control system for the desulfurization facility according to Embodiment 1 of the present invention. FIG. 4 is a block diagram of an operation control system for a desulfurization facility according to Embodiment 2 of the present invention. FIG. 5 is a flowchart showing the operation of the operation control system for the desulfurization facility according to Embodiment 2 of the present invention.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

[Embodiment 1]
The present embodiment will be described with reference to the drawings. 1 is a schematic diagram of an operation control system for a desulfurization facility according to Embodiment 1. FIG. As shown in FIG. 1, a desulfurization facility 1 includes an absorption tower 3 that removes SO ₂ (sulfur dioxide) in an exhaust gas 100 a from a boiler (for example, a coal fired boiler) 2 such as a thermal power plant, a control device 5, It has.

The exhaust gas 100a discharged from the boiler 2 is supplied to the absorption tower 3 while being pumped by the exhaust gas blower 2b interposed in the exhaust gas pipe 2a. In the exhaust gas treatment system including the desulfurization facility 1 according to the present embodiment, the exhaust gas 100a discharged from the boiler 2 is treated with NOx (nitrogen oxidation) by the denitration facility before reaching the absorption tower 3, although not clearly shown in the figure. The combustion ash is removed by a dust collector (for example, an electrostatic dust collector). Further, desulfurized flue gas 100b of the FGD 1 of the present embodiment is removed SO ₂ is removed CO ₂ by CO ₂ (carbon dioxide) recovery equipment.

The absorption tower 3 of the desulfurization facility 1 applied to such a flue gas treatment system is configured so that an absorption liquid 101 (hereinafter referred to as an absorption liquid) 101 containing limestone is brought into contact with the supplied exhaust gas 100a to thereby adjust the SO in the exhaust gas 100a. ₂ (sulfur dioxide) is absorbed by the limestone in the absorbent 101, and the desulfurized exhaust gas 100b from which SO ₂ has been removed is discharged.

  The absorption tower 3 stores an absorption liquid 101 at the bottom thereof. A limestone feeder 3 a is provided outside the absorption tower 3, and the limestone 102 is measured by the limestone feeder 3 a and supplied to the bottom of the absorption tower 3. Further, water 103 is supplied to the bottom of the absorption tower 3 through a water supply pipe 3b. That is, the absorption liquid 101 is generated by the limestone 102 and the water 103 supplied to the bottom of the absorption tower 3.

The absorption liquid 101 stored at the bottom in the absorption tower 3 is pumped by the absorption liquid circulation pump 3 c and supplied to the upper part in the absorption tower 3 through the absorption liquid pipe 3 d outside the absorption tower 3. Then, the absorption liquid 101 comes into contact with the exhaust gas 100a rising in the absorption tower 3 in the process of reaching the lower part in the absorption tower 3 while flowing down from the nozzle 3e provided in the upper part in the absorption tower 3. Thereby, SO ₂ contained in the exhaust gas 100a reacts with the limestone 102 of the absorbing liquid 101 (see the following formula 1), and SO ₂ is removed from the exhaust gas 100a. Then, the desulfurization exhaust gas 100b from which SO ₂ has been removed is discharged from the desulfurization facility 1 through the desulfurization exhaust gas pipe 3f connected to the top of the absorption tower 3. Further, the absorbing liquid 101 used for the removal of SO ₂ is stored at the bottom in the absorption tower 3.
SO ₂ + 1 / 2O ₂ + CaCO ₃ + 2H ₂ O → CaSO ₄ .2H ₂ O + CO ₂ Formula 1

  Further, a part of the absorbing liquid 101 stored at the bottom in the absorption tower 3 is depressurized via an extraction pipe 3g branched from the absorption liquid pipe 3d outside the absorption tower 3 while being pumped by the absorption liquid circulation pump 3c. Sent to 3h. The dehydrator 3h is constituted by, for example, a belt filter, dehydrates the absorbent 101 in the process of being conveyed by the belt filter, and is discharged out of the system as a byproduct gypsum 104. Moreover, the filtrate which dehydrated the absorption liquid 101 is utilized as the water 103 supplied to the bottom part of the absorption tower 3 in this Embodiment.

The bottom of the absorption tower 3 is supplied with the oxidizing air 105 fed by the oxidation blower 3i. For this reason, since the oxidizing liquid 105 is contained in the absorbing liquid 101, the oxidizing of the absorbing liquid 101 is promoted, so that the SO ₂ removal efficiency can be improved.

In the absorption tower 3 described above, the absorption liquid 101 supplied to the upper part of the absorption tower 3 through the absorption liquid pipe 3d is caused to flow down from the nozzle 3e, thereby contacting the exhaust gas 100a rising in the absorption tower 3. This is not the case. For example, although not shown in the figure, the absorbing liquid is supplied to the middle part of the absorption tower via the absorbing liquid pipe, and the absorbing liquid is ejected upward from the nozzle provided in the middle part of the absorption tower. As a result, the absorbing liquid becomes fine droplets while being dispersed in the upper part of the absorption tower, descends in the absorption tower, and comes into contact with the exhaust gas rising in the absorption tower. As a result, a larger gas-liquid contact area is secured and the gas-liquid contact efficiency is improved, so that the SO ₂ removal efficiency can be improved. In addition to the countercurrent contact described above, the contact between the absorbing liquid 101 and the exhaust gas 100a is not limited to the above-described countercurrent contact. There is a co-current contact that combines.

In the desulfurization facility 1 described above, as shown in FIG. 1, the exhaust gas blower 2b is provided with an exhaust gas blower power consumption detection unit 4a that detects the power consumption (exhaust gas blower power consumption a). Further, the absorption liquid circulation pump 3c is provided with a circulation pump power consumption detection unit 4b for detecting the power consumption (circulation pump power consumption b). The oxidation blower 3i is provided with an oxidation blower power consumption detection unit 4c that detects its power consumption (oxidation blower power consumption c). Further, the exhaust gas pipe 2a is provided with an inlet side SO ₂ concentration detector 4d that detects the SO ₂ concentration (inlet side SO ₂ concentration d) in the exhaust gas 100a reaching the absorption tower 3. The desulfurization exhaust gas pipe 3f is provided with an outlet side SO ₂ concentration detector 4e that detects the SO ₂ concentration (exit side SO ₂ concentration e) in the desulfurization exhaust gas 100b discharged from the absorption tower 3. The absorption liquid pipe 3d is provided with a limestone concentration detection unit 4f that detects the concentration of limestone 102 in the absorption liquid 101 (limestone concentration f). In addition, the exhaust gas pipe 2a has an exhaust gas flow rate detection unit 4g for detecting the flow rate (exhaust gas flow rate g) of the exhaust gas 100a reaching the absorption tower 3 together with the inlet side SO ₂ concentration detection unit 4d, and the temperature of the exhaust gas 100a reaching the absorption tower 3 An exhaust gas temperature detector 4 h that detects (exhaust gas temperature h) and an exhaust gas moisture concentration detector 4 i that detects the moisture concentration (exhaust gas moisture concentration i) of the exhaust gas 100 a reaching the absorption tower 3 are provided. Further, the boiler 2 is provided with a boiler fuel consumption detection unit 4j that detects the amount of fuel consumed (boiler fuel consumption j). The limestone feeder 3a is provided with a limestone supply amount detection unit 4k that detects the supply amount of limestone 102 (limestone supply amount k). The water supply pipe 3b is provided with a supply water flow rate detection unit 4m that detects the supply amount of the water 103 (supply water flow rate m). Further, the absorbing liquid pipe 3d is provided with an absorbing liquid flow rate detection unit 4n that detects the flow rate of the absorbing liquid 101 (absorbing liquid flow rate n).

And these exhaust gas blower power consumption a, circulation pump power consumption b, oxidation blower power consumption c, inlet side SO ₂ concentration d, outlet side SO ₂ concentration e, limestone concentration f, exhaust gas flow rate g, exhaust gas temperature h, exhaust gas moisture concentration Each data of i, boiler fuel consumption j, limestone supply amount k, supply water flow rate m, and absorption liquid flow rate n is input to the control device 5.

  The control device 5 will be described with reference to the block diagram of the operation control system for the desulfurization facility according to Embodiment 1 in FIG. The control device 5 is constituted by a microcomputer or the like. The control device 5 is provided with a storage unit 5a. The storage unit 5a includes a RAM, a ROM, and the like, and stores programs and data. In addition, the controller 5 supplies a voltage to the feeder motor (not shown) to operate the absorbent circulating pump drive unit 5b for applying a voltage when operating the absorbent circulating pump 3c and the limestone feeder 3a. A limestone feeder drive unit 5c is provided for placing. The control device 5 is provided with an input / output unit 5d. The input / output unit 5d includes a keyboard, a mouse, and a monitor. The control device 5 is provided with an information communication unit 5e. The information communication unit 5 e is for performing information communication with the information communication unit 6 f of the management device 6. The control device 5 comprehensively controls the absorption liquid circulation pump 3c and the limestone feeder 3a according to programs and data stored in advance in the storage unit 5a based on information input from the management device 6.

The management apparatus 6 is demonstrated with reference to the block diagram of the operation control system of the desulfurization equipment which concerns on Embodiment 1 of FIG. The management device 6 is composed of a microcomputer or the like. As shown in FIG. 1, the management device 6 is connected to the control device 5 via the network N, and the exhaust gas blower power consumption a, the circulation pump power consumption b, the oxidation blower power consumption c, the inlet side SO ₂ concentration d, Control each data of outlet side SO ₂ concentration e, limestone concentration f, exhaust gas flow rate g, exhaust gas temperature h, exhaust gas moisture concentration i, boiler fuel consumption j, limestone supply amount k, supply water flow rate m, and absorption liquid flow rate n. Obtained from the device 5.

  The management device 6 is provided with a storage unit 6a. The storage unit 6a includes a RAM, a ROM, and the like, and stores programs and data. The storage unit 6a has an evaluation index formula database 6aa, an absorption liquid circulation pump supply voltage database 6ab, and a limestone feeder supply voltage database 6ac.

The evaluation index formula database 6aa is obtained from the control device 5, the exhaust gas blower power consumption a, the circulation pump power consumption b, the oxidation blower power consumption c, the inlet side SO ₂ concentration d, the outlet side SO ₂ concentration e, the limestone concentration f, Formula 2 for calculating the evaluation index E based on each data of the exhaust gas flow rate g, the exhaust gas temperature h, the exhaust gas moisture concentration i, the boiler fuel consumption j, the limestone supply amount k, the supply water flow rate m, and the absorption liquid flow rate n ~ Equation 5 is stored.
E = TMG ... Equation 2
T = (D × DP) + (L × LP) + (W × WP) + (F × FP) Equation 3
M = S × SP Expression 4
G = H × HP ... Formula 5

In the above equation 2, T is a desulfurization facility operating cost as an expenditure market price of various expenditures generated in accordance with the operation of the desulfurization facility 1, and is obtained by the above equation 3. Further, in the above formula 2, M is the SO ₂ sales amount (SO ₂ emission right) as the revenue market price of revenues generated in accordance with the operation of the desulfurization facility 1, and is obtained by the above formula 4. In the above formula 2, G is a by-product gypsum sales amount or a by-product gypsum processing cost as a revenue market price of revenues generated according to the operation of the desulfurization facility 1 (in the case of a by-product gypsum processing cost, it is a negative value) ) And is obtained by the above equation 5. That is, the evaluation index E is calculated from the desulfurization facility operating cost T as the expenditure market price of various expenditures generated according to the operation of the desulfurization facility 1, and the SO ₂ as the revenue market price of revenues generated according to the operation of the desulfurization facility 1 The sales amount M and the by-product gypsum sales amount (or by-product gypsum processing cost) G are subtracted.

In the above formula 3, D is the power consumption of the desulfurization facility 1 and is obtained by adding the exhaust gas blower power consumption a, the circulation pump power consumption b, and the oxidation blower power consumption c described above. DP is a power unit price. L is a limestone consumption, those obtained by the following equation 6, the obtained SO ₂ removal amount S (the amount of SO ₂ removed from the flue gas 100a) by the following equation 7, the limestone purity f ', the absorbing liquid It is calculated | required from the relationship with the limestone density | concentration f in 101. LP is limestone unit price (absorbing liquid material unit price). W is the amount of water supplied to the desulfurization facility 1 and is determined from the relationship between the exhaust gas flow rate g, the exhaust gas temperature h, and the exhaust gas moisture concentration i described above. WP is the unit price of water supply. F is a fuel consumption amount in the boiler 2 and corresponds to the above-described boiler fuel consumption amount j. FP is the fuel unit price of the boiler 2.
L = S × 100 / limestone purity f ′ [100 = CaCO ₃ molecular weight] Formula 6
S = (inlet side SO ₂ concentration d−outlet side SO ₂ concentration e) × exhaust gas flow rate g / 22.4 × 10 ^6.
The limestone concentration f is the concentration of excess limestone in the absorption liquid 101. If this is constant, the limestone consumption L changes only in accordance with the SO ₂ removal amount S. However, since the desulfurization performance changes depending on the limestone concentration f, when the demand for the desulfurization performance changes, it is necessary to temporarily add excess limestone to the limestone consumption L.

In the above formula 4, S is the SO ₂ removal amount described above. SP is the SO ₂ transaction unit price.

In Formula 5, H is the amount of byproduct gypsum produced, and is determined from the relationship between the SO ₂ removal amount S, the limestone purity f ′, and the limestone concentration f in the absorbing liquid 101. HP is the by-product gypsum sales unit price (or by-product gypsum processing unit price (in the case of by-product gypsum processing unit price, it is a negative value)).

The absorption liquid circulation pump supply voltage database 6ab is such that the evaluation index E described above is minimized, that is, the desulfurization facility operating cost T, which is the expenditure market price of various expenditures generated according to the operation of the desulfurization facility 1, is minimized. In order to set the delivery amount of the absorption liquid 101 to be sent to the absorption tower 3, the absorption liquid circulation pump information for applying a voltage to the absorption liquid circulation pump 3c is stored. In this absorption liquid circulation pump information, the relationship between the absorption liquid delivery amount (absorption liquid flow rate n) by the absorption liquid circulation pump 3c and the power consumption D and SO ₂ removal amount S of the desulfurization facility 1 is theoretical or experimental. It is the one requested by

The limestone feeder supply voltage database 6ac has the absorption index so that the evaluation index E described above is minimized, that is, the desulfurization facility operating cost T, which is the expenditure market price of various expenditures generated according to the operation of the desulfurization facility 1, is minimized. In order to set the supply amount of the absorbent 101 supplied to the feeder 3, feeder voltage information for applying a voltage to a feeder motor (not shown) of the limestone feeder 3a is stored. In this feeder voltage information, the relationship between the limestone supply amount k and the SO ₂ removal amount S by the limestone feeder 3a is obtained in advance by a theoretical formula or an experimental formula.

  Further, the management device 6 is provided with an expenditure market price information input unit 6b. In this expenditure market price information input unit 6b, a power unit price DP, a limestone unit price LP, a supply water unit price WP, and a fuel unit price FP for obtaining the desulfurization facility operating cost T as the expenditure market price are input. The electric power unit price DP, the limestone unit price LP, and the supply water unit price WP are obtained by being automatically input from the Internet or manually by an operator.

The management device 6 is provided with an income market price information input unit 6c. In the revenue market price information input unit 6c, an SO ₂ transaction unit price SP for obtaining the SO ₂ sales amount M as the revenue market price and a by-product gypsum sales amount (or by-product gypsum processing cost) G as the revenue market price are stored. The by-product gypsum sales unit price (or by-product gypsum processing unit price) HP for obtaining is input. Such SO ₂ transaction unit price SP and by-product gypsum sales unit price (or by-product gypsum processing unit price) HP are obtained by being automatically input from the Internet or manually by an operator.

Further, the management device 6 is provided with a processing unit 6d. The processing unit 6d includes a desulfurization facility operating cost calculation unit 6da, an SO ₂ sales calculation unit 6db, a by-product gypsum sales calculation unit (or by-product gypsum processing cost calculation unit) 6dc, an evaluation index calculation unit 6dd, and an absorption liquid delivery amount setting unit. 6de and a limestone supply amount setting unit 6df.

The desulfurization facility operating cost calculation unit 6da calculates the desulfurization facility operating cost T from the above equation 3 stored in the evaluation index formula database 6aa of the storage unit 6a. That is, exhaust Gasuburoa power a, circulating pump power consumption b, and obtains the power consumption D of desulfurization 1 by adding the oxidizing blower power consumption c, the exhaust gas subtracts the outlet SO ₂ concentration e from the inlet side SO ₂ concentration d The limestone consumption L is determined from the SO ₂ removal amount S multiplied by the flow rate g, the limestone purity f ′, and the limestone concentration f, and the supply water amount W is determined from the relationship between the exhaust gas flow rate g, the exhaust gas temperature h, and the exhaust gas moisture concentration i. Further, the fuel consumption F is obtained from the boiler fuel consumption j, and the desulfurization facility operating cost T is calculated from the power unit price DP, the limestone unit price LP, the supply water unit price WP, and the fuel unit price FP acquired from the expenditure market price information input unit 6b. .

The SO ₂ sales amount calculation unit 6db calculates the SO ₂ sales amount M from the above formula 4 stored in the evaluation index formula database 6aa of the storage unit 6a. That is, by subtracting the outlet side SO ₂ concentration e from the inlet side SO ₂ concentration d and multiplying by the exhaust gas flow rate g, the SO ₂ removal amount S is obtained, and the SO ₂ transaction unit price SP acquired from the revenue market price information input unit 6c ₂ Calculate sales M.

Byproduct gypsum sales amount calculation unit (or byproduct gypsum processing cost calculation unit) 6dc calculates byproduct gypsum sales amount (byproduct gypsum processing cost) G from the above equation 5 stored in the evaluation index formula database 6aa of the storage unit 6a. To do. That is, the amount of byproduct gypsum produced H is obtained from the SO ₂ removal amount S obtained by subtracting the outlet side SO ₂ concentration e from the inlet side SO ₂ concentration d and multiplied by the exhaust gas flow rate g, the limestone purity f ′, and the limestone concentration f, and further the revenue market. By-product gypsum sales (by-product gypsum processing cost) G is calculated from the by-product gypsum sales unit price (or by-product gypsum processing unit price) HP acquired from the price information input unit 6c.

The evaluation index calculation unit 6dd calculates the evaluation index E from the above formula 2 stored in the evaluation index formula database 6aa of the storage unit 6a. That is, the desulfurization equipment operation cost T calculated by desulfurization equipment operation cost calculation unit 6da, SO ₂ sales calculator SO ₂ sales calculated in 6db M, and by-product gypsum sales calculator (or by-product gypsum processing cost calculation unit) The evaluation index E is calculated from the amount of by-product gypsum sales (cost of by-product gypsum treatment) G calculated at 6 dc.

  The absorption liquid delivery amount setting unit 6de uses the absorption liquid circulation pump information stored in the absorption liquid circulation pump supply voltage database 6ab of the storage unit 6a to minimize the evaluation index E calculated by the evaluation index calculation unit 6dd. In addition, the amount of the absorption liquid 101 to be sent to the absorption tower 3, that is, the voltage applied to the absorption liquid circulation pump 3c is set.

  The limestone supply amount setting unit 6df absorbs the absorbent 101 so that the evaluation index E calculated by the evaluation index calculation unit 6dd is minimized based on the feeder voltage information stored in the limestone feeder supply voltage database 6ac of the storage unit 6a. The supply amount of limestone 102 which is a material forming the above, that is, the voltage applied to the feeder motor (not shown) of the limestone feeder 3a is set.

  The management device 6 is provided with an input / output unit 6e. The input / output unit 6e includes a keyboard, a mouse, and a monitor. In addition, the management device 6 is provided with an information communication unit 6f. The information communication unit 6 f is for performing information communication with the information communication unit 5 e of the control device 5. Based on the information input from the control device 5, the management device 6 controls the control device 5 in an integrated manner with respect to the absorbent circulating pump 3c and the limestone feeder 3a in accordance with programs and data stored in advance in the storage unit 6a. To output information.

  The operation control of the desulfurization facility by the control device 5 and the management device 6 described above will be described with reference to the flowchart showing the operation of the operation control system of the desulfurization facility according to the first embodiment of FIG.

As shown in FIG. 3, first, in the control device 5, the exhaust gas blower power consumption a, the circulation pump power consumption b, the oxidation blower power consumption c, the inlet side SO ₂ concentration d, the outlet side SO ₂ concentration e, the limestone concentration f, Each data of the limestone purity f ′, the exhaust gas flow rate g, the exhaust gas temperature h, the exhaust gas moisture concentration i, the boiler fuel consumption j, the limestone supply amount k, the supply water flow rate m, and the absorption liquid flow rate n is output to the management device 6 ( Step ST1).

Next, the management device 6 inputs each of the above data from the control device 5 (step ST2), the desulfurization facility operation cost calculation unit 6da calculates the desulfurization facility operation cost T, and the SO ₂ sales calculation unit 6db The SO ₂ sales amount M is calculated, the by-product gypsum sales calculating unit (or by-product gypsum processing cost calculating unit) 6dc calculates the by-product gypsum sales amount (by-product gypsum processing cost) G, and the evaluation index calculating unit 6dd evaluates it. An index E is calculated (step ST3).

  Next, the management device 6 sets the amount of the absorption liquid 101 to be sent to the absorption tower 3 (that is, the voltage applied to the absorption liquid circulation pump 3c) so that the evaluation index E is minimized in the absorption liquid delivery amount setting unit 6de. At the same time, in the limestone supply amount setting unit 6df, the supply amount of limestone 102 which is a material constituting the absorbing liquid 101 (that is, a feeder motor (not shown) of the limestone feeder 3a) is added so that the evaluation index E is minimized. Voltage) is set (step ST4).

Finally, the control device 5, while the SO ₂ removal amount S within a predetermined range, the set voltage of the absorbent circulating pump 3c in the management apparatus 6, and the voltage of the feeder motor limestone feeder 3a (not shown) Accordingly, the absorption liquid circulation pump 3c and the limestone feeder 3a are driven (step ST5).

As described above, in the operation control system for the desulfurization facility according to the first embodiment, the expenditures generated in accordance with the operation of the desulfurization facility 1 while keeping the SO ₂ removal amount S obtained by removing SO ₂ from the exhaust gas 100a within a predetermined range. Evaluation by subtracting the revenue market price (SO ₂ sales M, by-product gypsum sales (by-product gypsum treatment cost) G) from the expenditure market price (desulfurization facility operating cost T) and the revenue generated by the operation of the desulfurization facility 1 In a mode in which the index E is minimized, the amount of the absorbing liquid 101 sent to the absorption tower 3 and the amount of the material (limestone 102) constituting the absorbing liquid 101 are set.

According to the operation control system of this desulfurization facility, when the revenue market price (SO ₂ sales M, by-product gypsum sales G) is high, the SO ₂ removal amount S is increased, and conversely, the revenue market price (SO ₂ When the sales amount M and the by-product gypsum sales amount G) are low, the desulfurization equipment operating cost T is controlled to be reduced. Thus, the operating conditions of the desulfurization facility 1 can be optimized according to the revenue market price (SO ₂ sales M, by-product gypsum sales (by-product gypsum processing cost) G). As a result, the exhaust gas 100a conditions (inlet side SO ₂ concentration d, outlet side SO ₂ concentration e, limestone concentration f, exhaust gas flow rate g, exhaust gas temperature h), SO ₂ sales M, and relatively slowly fluctuate. Each unit price (power unit price DP, limestone unit price LP, supply water unit price WP, fuel unit price FP) can be used to perform economical operation that always minimizes the cost caused by the operation of the desulfurization facility 1. Become.

  Moreover, depending on the conditions, if the revenue market price (M, G) is larger than the expenditure market price (T) in the above equation 2 (E = T-M-G), the evaluation index E becomes negative, and the desulfurization equipment It is also possible to record profits by driving 1.

  In the operation control system for the desulfurization facility according to the first embodiment, the management device 6 is connected to the control device 5 in the desulfurization facility 1 via the network N so as to be communicable. As a result, operation control of the desulfurization facility 1 can be performed at a remote location.

  In the operation control system for the desulfurization facility according to the first embodiment, as shown in FIG. 1, the management device 6 is communicably connected to the control devices 5 in the plurality of desulfurization facilities 1 via the network N. . FIG. 2 shows a form in which the control device 5 and the management device 6 in one desulfurization facility 1 are connected in a one-to-one relationship. However, the control device 5 and the management device 6 in the plurality of desulfurization facilities 1 are connected to each other. When connected in a many-to-one relationship, in the management device 6, corresponding to each control device 5, a storage unit 6a, an expenditure market price information input unit 6b, an income market price information input unit 6c, a processing unit 6d, The input / output unit 6e and the information communication unit 6f function. As a result, the operation control of the plurality of desulfurization facilities 1 can be performed in a remote place. When the control device 5 and the management device 6 in the desulfurization facility 1 are connected in a one-to-one relationship, the control device 5 and the management device 6 are not connected via the network N, and the management device 6 is desulfurized. It may be included in the control device 5 of the facility 1.

As the absorption liquid to absorb SO _2, it has been described desulfurization 1 lime gypsum method of applying the absorption liquid 101 containing limestone 102, not limited thereto. For example, the embodiments described above can be applied to other wet desulfurization facilities such as a water mug method and a caustic soda method. In that case, the limestone unit price LP is changed to a magnesium hydroxide unit price or a caustic soda unit price.

[Embodiment 2]
The present embodiment will be described with reference to the drawings. FIG. 4 is a block diagram of an operation control system for a desulfurization facility according to Embodiment 2 of the present invention. In the second embodiment described below, the same reference numerals are given to the same components as those in the first embodiment described above, and the description thereof is omitted.

  The desulfurization facility 1 shown in FIG. 4 further includes an expenditure market price information database 6ad and an income market price information database 6ae in the storage unit 6a in the management device 6 as compared with the first embodiment described above.

  The expenditure market price information database 6ad is a unit price of electricity DP, a unit price of limestone LP, a unit price of supply water WP, and a unit price of fuel FP as the expenditure market price input to the expenditure market price information input unit 6b. Remember.

The revenue market price information database 6ae stores the SO ₂ transaction unit price SP for obtaining the SO ₂ sales amount M as the revenue market price input to the revenue market price information input unit 6c, and by-product gypsum sales (or by-product gypsum processing costs). ) Store by-product gypsum sales unit price (or by-product gypsum processing unit price) HP for obtaining G.

  The operation control of the desulfurization facility by the control device 5 and the management device 6 will be described with reference to the flowchart showing the operation of the operation control system of the desulfurization facility according to the second embodiment of FIG.

  As shown in FIG. 5, first, the management device 6 acquires the expenditure market price stored in the expenditure market price information database 6ad and the income market price stored in the income market price information database 6ae for a predetermined period in the past. (Step ST11).

  Next, in the evaluation index calculation unit 6dd, the management device 6 calculates the predicted evaluation index Ea by subtracting the income market price from the acquired expenditure market price (step ST12). The calculation of the predicted evaluation index Ea is the same as the evaluation index E of the first embodiment described above.

  Next, the management device 6 sends the absorption liquid 101 sent to the absorption tower 3 (that is, the voltage applied to the absorption liquid circulation pump 3c) so that the predicted evaluation index Ea is minimized in the absorption liquid delivery quantity setting unit 6de. In addition, in the limestone supply amount setting unit 6df, the supply amount of limestone 102 that is the material constituting the absorbent 101 (that is, a feeder motor (not shown) of the limestone feeder 3a) so that the predicted evaluation index Ea is minimized. Is set (step ST13).

Finally, the control device 5, while the SO ₂ removal amount S within a predetermined range, the set voltage of the absorbent circulating pump 3c in the management apparatus 6, and the voltage of the feeder motor limestone feeder 3a (not shown) Accordingly, the absorption liquid circulation pump 3c and the limestone feeder 3a are driven (step ST14).

As described above, in the operation control system for the desulfurization facility according to the second embodiment, the revenue market price (SO ₂ sales M, by-product gypsum sales ( The amount of absorption liquid 101 sent to the absorption tower 3 and the supply amount of the material (limestone 102) constituting the absorption liquid 101 are set in such a manner that the predicted evaluation index Ea obtained by subtracting the byproduct gypsum processing cost G) is minimized. .

According to the operation control system of this desulfurization facility, when the past revenue market price (SO ₂ sales M, by-product gypsum sales G) is high, the SO ₂ removal amount S is increased, and conversely the past revenue market. When the price (SO ₂ sales M, by-product gypsum sales G) is low, the desulfurization equipment operating cost T is set to be low. Thus, it becomes possible to predict the optimal operating conditions of the desulfurization facility 1 according to the past revenue market price (SO ₂ sales amount M, by-product gypsum sales amount (by-product gypsum treatment cost) G). As a result, the manager of the facility can make a prior arrangement for materials such as utilities (for example, limestone 102) by planning in advance. The predicted evaluation index Ea can be corrected by the evaluation index E of the first embodiment described above.

  In the operation control system for the desulfurization facility according to the second embodiment, the management device 6 is connected to the control device 5 in the desulfurization facility 1 via the network N so as to be communicable. As a result, operation control of the desulfurization facility 1 can be performed at a remote location.

  In the operation control system for the desulfurization facility according to the second embodiment, as shown in FIG. 1, the management device 6 is communicably connected to the control devices 5 in the plurality of desulfurization facilities 1 via the network N. . In FIG. 4, the control device 5 and the management device 6 in one desulfurization facility 1 are connected in a one-to-one relationship, but the control device 5 and the management device 6 in the plurality of desulfurization facilities 1 are connected. When connected in a many-to-one relationship, in the management device 6, corresponding to each control device 5, a storage unit 6a, an expenditure market price information input unit 6b, an income market price information input unit 6c, a processing unit 6d, The input / output unit 6e and the information communication unit 6f function. As a result, the operation control of the plurality of desulfurization facilities 1 can be performed in a remote place. When the control device 5 and the management device 6 in the desulfurization facility 1 are connected in a one-to-one relationship, the control device 5 and the management device 6 are not connected via the network N, and the management device 6 is desulfurized. It may be included in the control device 5 of the facility 1.

  As described above, the operation control system for a desulfurization facility according to the present invention is suitable for performing economical operation according to various market prices.

DESCRIPTION OF SYMBOLS 1 Desulfurization equipment 2 Boiler 2a Exhaust pipe 2b Exhaust blower 3 Absorption tower 3a Limestone feeder 3b Water supply pipe 3c Absorption liquid circulation pump 3d Absorption liquid pipe 3e Nozzle 3f Desulfurization exhaust pipe 3g Extraction pipe 3h Dehydrator 3i Oxidation blower 4a Exhaust blower power consumption Detection unit 4b Circulating pump power consumption detection unit 4c Oxidation blower power consumption detection unit 4d Inlet side SO ₂ concentration detection unit 4e Outlet side SO ₂ concentration detection unit 4f Limestone concentration detection unit 4g Exhaust gas flow rate detection unit 4h Exhaust gas temperature detection unit 4i Exhaust gas moisture Concentration detection unit 4j Boiler fuel consumption detection unit 4k Limestone supply amount detection unit 4m Supply water flow rate detection unit 4n Absorbed liquid flow rate detection unit 5 Controller 5a Storage unit 5b Absorption liquid circulation pump drive unit 5c Limestone feeder drive unit 5d Input / output unit 5e Information communication unit 6 Management device 6a Storage unit 6b Expenditure market price information Information input part 6c Revenue market price information input part 6d Processing part 6e Input / output part 6f Information communication part 100a Exhaust gas 100b Desulfurization exhaust gas 101 Absorbent liquid 102 Limestone 103 Water 104 Byproduct gypsum 105 Air for oxidation N Network E Evaluation index Ea Predictive evaluation index T Operating cost of desulfurization equipment M SO ₂ sales G By-product gypsum sales S SO ₂ removal

Claims (4)

In operation control system of desulfurization comprising an absorption tower for discharging the desulfurized flue gas SO ₂ is removed SO ₂ while absorbed into the absorbing solution in the exhaust gas by contacting the absorption liquid to the exhaust gas,
The amount of SO ₂ removed by removing SO ₂ from the exhaust gas is within a predetermined range, and the revenue market price of revenues generated according to the operation of the desulfurization facility is subtracted from the expenditure market price of the expenditures generated according to the operation of the desulfurization facility. An operation control system for a desulfurization facility, comprising a management device for setting a delivery amount of an absorption liquid to be sent to the absorption tower and a supply amount of a material constituting the absorption liquid in such a manner that the evaluation index is minimized. .   The management device is configured such that, for a predetermined period in the past, a predicted evaluation index obtained by subtracting the revenue market price from the expenditure market price is minimized, and the amount of the absorption liquid sent to the absorption tower and the absorption liquid are formed. 2. The operation control system for a desulfurization facility according to claim 1, wherein a supply amount of the material is set in advance. SO ₂ concentration in the exhaust gas, and acquires the SO ₂ concentration in the desulfurized flue gas, and a control device for controlling the supply of material forming delivery, and the absorption liquid in the absorption liquid to the absorption tower, the absorbing A desulfurization facility for removing SO ₂ in the exhaust gas is constituted by a tower, an absorption liquid sending section that sends an absorption liquid to the absorption tower, and a material supply section that supplies a material that forms the absorption liquid.
The operation control system for a desulfurization facility according to claim 1 or 2, wherein the management device is connected to the control device in the desulfurization facility via a network so as to be communicable.   The operation control system for a desulfurization facility according to claim 3, wherein the management device is connected to the control devices in the plurality of the desulfurization facilities via a network.

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