JP2020001030A - Exhaust gas mercury removal system - Google Patents

Abstract

To decrease an amount of emission of mercury contained in an exhaust gas which is emitted into atmosphere.SOLUTION: An exhaust gas mercury removal system 1 has: a mercury concentration meter 11 which measures a concentration of mercury contained in an exhaust gas which is emitted from a dust collector 7 for dust removal processing of an exhaust gas E containing mercury, and outputs an output value corresponding to a measurement result; an active carbon feeder 12 which feeds active carbon to the exhaust gas on an upstream side of the dust collector 7; and a controller 13 which controls the active carbon feeder 12 on the basis of the output value. The controller 13 controls the active carbon feeder 12 so as to feed active carbons of a specified quantity when the output value is less than a first threshold, and controls the active carbon feeder 12 so as to continuously feed active carbons of a supply amount corresponding to an output value change speed when the output value is the first threshold or more.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an exhaust gas mercury removal system.

Exhaust gas emitted from plants such as waste treatment plants equipped with refuse incinerators and coal-fired power plants equipped with boilers can contain highly toxic mercury. Various removal systems have been studied.
In Patent Document 1, the concentration of mercury contained in exhaust gas discharged from a refuse incinerator is measured by a mercury concentration meter installed downstream of a bag filter that is a dust collecting device, and the mercury concentration is measured in a pipe upstream of the bag filter. A system for adjusting the supply amount of the supplied activated carbon according to the output value of a mercury concentration meter is disclosed.

Japanese Patent No. 6070971

In the above-mentioned conventional system, a small amount and a constant amount of activated carbon are continuously supplied to the exhaust gas continuously regardless of the concentration of mercury contained in the exhaust gas (hereinafter referred to as “exhaust gas mercury concentration”). Therefore, even if the mercury concentration of the exhaust gas suddenly increases, no special treatment is required until the mercury concentration of the exhaust gas can be absorbed and removed by the activated carbon.
However, if the mercury concentration in the exhaust gas exceeds the amount of mercury adsorbed by the activated carbon, that is, the treated amount of the activated carbon, the exhaust gas containing mercury that could not be completely treated by the activated carbon is discharged from the stack into the outside of the plant. Become.

  Therefore, in the conventional system, the mercury concentration meter measures the mercury concentration downstream of the dust collector, and when the output value of the mercury concentration meter exceeds the processing amount permitted by the activated carbon, the amount increased accordingly (the Activated carbon was supplied upstream of the dust collector in an amount sufficient to adsorb the mercury at the concentration indicated by the output value.

  However, since the mercury concentration in the exhaust gas rapidly increases in a short time (several tens of seconds to several minutes), the amount of activated carbon necessary and sufficient to treat the mercury of the concentration measured downstream of the dust collector is required. Even if the mercury is supplied upstream of the dust collector, the mercury concentration at the point of supply is sharply increasing, and thus far exceeds the amount of the activated carbon treated. There was a risk that exhaust gases containing mercury in excess of standard values would be emitted from the chimney.

As described above, if a constant amount of activated carbon is continuously supplied to the exhaust gas in a large amount, not always in a small amount, this risk is reduced, but it is uneconomical.
That is, in the conventional system, it was difficult to economically and effectively reduce the amount of mercury contained in the exhaust gas (the amount of mercury released to the atmosphere).

  The present invention relates to a system having the same configuration as that of the related art, that is, a method of measuring the concentration of mercury contained in exhaust gas downstream of a dust collector with a mercury concentration meter, and using activated carbon supplied to a pipe upstream of the dust collector. Although it is a system that adjusts the supply amount according to the output value of the mercury concentration meter, an exhaust gas mercury removal system that can reduce the amount of mercury emitted to the atmosphere more economically and effectively than before is provided. The purpose is to provide.

  The exhaust gas mercury removal system of the present invention measures the concentration of the mercury contained in the exhaust gas discharged from the dust collector that removes the mercury-containing exhaust gas, and outputs an output value corresponding to the measurement result. A concentration meter, an activated carbon supply device that supplies activated carbon to the exhaust gas upstream of the dust collector, and a control device that controls the activated carbon supply device based on the output value, wherein the control device includes: When the output value is less than the first threshold, the activated carbon supply device is controlled so as to supply a predetermined amount of the activated carbon, and the output value is equal to or more than the first threshold, and the rising speed of the output value is equal to the first value. If the rising speed of the output value becomes 0 or more after supplying the activated carbon of the first supply amount greater than the predetermined amount and supplying the activated carbon of the first supply amount, , The first supply amount Controlling the activated carbon supply device to supply a larger second supply amount of the activated carbon, the output value is equal to or more than the first threshold, and the output value is increasing at a rate equal to or greater than the first increasing rate. If less than the second ascent rate, after controlling the activated carbon supply device to supply the activated carbon of the second supply amount, after supplying the activated carbon of the first supply amount or the second supply amount When the rising speed of the output value is less than 0, the supply value of the activated carbon at that time is maintained until the output value becomes less than a second threshold value larger than the first threshold value, and the output value is When the value is less than a second threshold, the supply amount of the activated carbon at the time is reduced, and when the output value is less than a third threshold smaller than the first threshold, the predetermined amount of the activated carbon is supplied. The activated carbon supply device is controlled to perform the above operation.

  According to such a configuration, the supply amount of the activated carbon can be changed according to the speed of the change of the output value of the mercury concentration meter, and the activated carbon can be continuously supplied. That is, whether the mercury concentration in the exhaust gas flowing through the measurement location of the mercury concentration meter rapidly rises, levels off, or falls after the measurement of the mercury concentration, or changes in the output value of the mercury concentration meter. Based on the speed, the supply amount of the activated carbon supplied upstream of the dust collecting device can be significantly increased, moderately increased, maintained, or reduced, respectively, in accordance with the speed. In other words, since the appropriate amount of activated carbon is supplied in advance by predicting the change in mercury concentration at the activated carbon supply location, the amount of mercury in the exhaust gas discharged to the atmosphere can be reduced economically and effectively. be able to.

  In addition, when the ascending speed increases rapidly, the supply amount of the activated carbon can be greatly increased in advance, and when the ascending speed gradually increases, it can be increased in advance and stepwise. In addition, if the rising speed is 0 or more even after the activated carbon has been once increased and supplied, the activated carbon is further increased and supplied. That is, since the amount of activated carbon is increased and supplied in multiple stages in accordance with the rising speed of the mercury concentration in the exhaust gas, the amount of mercury in the exhaust gas can be reduced more economically and effectively.

  Further, when no particular treatment is performed, the exhaust gas mercury concentration may gradually decrease over a long period of time (from several tens of minutes to several hours) after reaching the peak. Therefore, in this configuration, regardless of the speed at which the exhaust gas mercury concentration decreases (hereinafter, referred to as “down speed”, which corresponds to a case where the exhaust gas mercury concentration increasing speed is less than 0), the exhaust gas mercury concentration is equal to the predetermined value (secondary speed). Until the value falls below a threshold value (for example, a legal reference value), the mercury concentration in the exhaust gas is rapidly reduced while maintaining the supply amount of activated carbon at that time. If it is less than the predetermined value, the amount of activated carbon is reduced and supplied according to the rate of decrease of the mercury concentration of the exhaust gas. For this reason, after reaching the peak, the exhaust gas mercury concentration, which gradually decreases over a long period of time (several tens of minutes to several hours), can be rapidly reduced. Since the amount of activated carbon is reduced step by step, the amount of mercury in the exhaust gas can be reduced more economically and effectively.

  In the exhaust gas mercury removal system, the result of the measurement may be the concentration of the mercury at the time of the measurement.

  According to such a configuration, the output value corresponding to the measurement result of the mercury concentration meter is a value corresponding to the mercury concentration itself at the time of the measurement. Therefore, compared with the case of using a mercury concentration meter whose output value is the average value of mercury concentrations at a plurality of measurement points, not only the response speed when supplying activated carbon is increased, but also the output value of the mercury concentration meter Since the rate of change is not evened, the amount of mercury in the exhaust gas can be reduced more economically and effectively.

  In the exhaust gas mercury removal system, the activated carbon may be a halogen-impregnated activated carbon.

  According to such a configuration, it is less susceptible to the presence form and coexisting gas of mercury than ordinary activated carbon, so that stable and high mercury removal performance can be obtained. Mercury emissions can be reduced.

  The exhaust gas mercury removal system further includes a refuse incinerator, a cooling tower located downstream of the refuse incinerator, and upstream of the dust collector, wherein the dust collector is a bag filter, The exhaust gas is discharged from the refuse incinerator, and when the output value is equal to or greater than the first threshold value, the control device may control the cooling tower to lower the temperature of the exhaust gas.

  According to such a configuration, the amount of mercury removed can be increased by controlling the cooling tower to lower the temperature of the exhaust gas, so that mercury emission in the exhaust gas can be more economically and effectively reduced. The amount can be reduced.

  In the exhaust gas mercury removal system, the dust collection device is a bag filter, and a refuse incinerator, a cooling tower disposed downstream of the refuse incinerator, and upstream of the bag filter, and from the bag filter. A fly ash circulator for conveying the discharged fly ash upstream of the bag filter and downstream of the temperature reducing tower to supply the exhaust ash to the exhaust gas; The activated carbon of the reaction may be used to reduce the emission of the mercury in the exhaust gas.

  According to such a configuration, since unreacted activated carbon contained in fly ash discharged from the bag filter can be reused, the supply amount of new activated carbon can be reduced, and more economically, Emission of mercury in exhaust gas can be reduced.

  According to the present invention, an appropriate amount of activated carbon is supplied in advance by predicting a change in mercury concentration based on the speed of change in the output value of the mercury concentration meter, so that the air emission can be reduced economically and effectively. It is possible to reduce the amount of mercury emitted in the exhaust gas.

It is a schematic structure figure of an exhaust gas mercury removal system of an embodiment of the present invention. It is a flow chart explaining control of an exhaust gas mercury removal system of an embodiment of the present invention. It is a schematic structure figure of an exhaust gas mercury removal system of a modification of the present invention. It is a schematic structure figure of an exhaust gas mercury removal system of a modification of the present invention.

  Hereinafter, an exhaust gas mercury removal system according to an embodiment of the present invention will be described in detail with reference to the drawings. The exhaust gas mercury removal system of the present invention can be applied to any plant including a cleaning plant equipped with a refuse incinerator and a coal-fired power plant equipped with a boiler, as long as the plant discharges exhaust gas containing mercury. Hereinafter, an incineration plant (refuse treatment plant) equipped with a waste incinerator will be described as an embodiment.

  As shown in FIG. 1, a refuse treatment plant 1 (exhaust gas mercury treatment system) includes a refuse incinerator 3 (for example, a progressive stoker furnace) for incinerating objects to be incinerated such as refuse, and a refuse incinerator 3. A boiler 4 that exchanges heat with the exhaust gas E that has passed through, a temperature-reducing tower 6 that sprays water or the like onto the exhaust gas E that has passed through the boiler 4 to reduce the temperature thereof, A dust collector (bag filter) 7 for removing dust, a pipe (duct) 9a for connecting the cooling tower 6 and the dust collector 7 to allow the exhaust gas E to pass through, and the exhaust gas E removed by the dust collector 7 to the atmosphere. A chimney 8 to be discharged, a pipe (duct) 9b connecting the dust collecting device 7 and the chimney 8 to pass the exhaust gas E, and a concentration of mercury contained in the exhaust gas E disposed in the pipe 9b and flowing inside the pipe 9b ( Mercury concentration meter 11 for measuring mercury concentration in exhaust gas, and piping 9 Activated carbon supply device 12 for supplying the activated carbon in the interior of, and a controller 13 for controlling the activated carbon supply device 12 in accordance with the output value of the mercury concentration meter 11.

  The activated carbon supply device 12 includes a hopper 14 in which activated carbon is stored, and a feeder 15 for supplying the activated carbon from the hopper 14 to the inside of the pipe 9a. The feeder 15 is, for example, a rotary feeder. When the feeder 15 is a rotary feeder, the control device 13 can control to increase or decrease the supply amount of the activated carbon by increasing or decreasing the rotation speed of the rotary feeder.

  The mercury concentration meter 11 is a continuous mercury concentration meter that automatically and continuously outputs an output value at a predetermined time interval (for example, every 20 seconds). Further, the mercury concentration meter 11 uses a plurality of measured values measured at predetermined time intervals as measurement results and transmits an output value corresponding to an average value of the plurality of measured values to the control device 13. Alternatively, a mercury concentration meter that does not use an average value as an output value, uses only one measured value itself at the time of measurement as a measurement result, and transmits the corresponding output value to the control device 13 may be used. Therefore, in each case, the output value of the mercury concentration meter 11 can be said to be a value "corresponding to the measurement result". The output value of the mercury concentration meter 11 is generally a digital value. In some cases, (1) the value of the mercury concentration in the exhaust gas itself is indicated, or (2) the value is encrypted and output by the mercury concentration meter 11 and controlled. In some cases, the value of the mercury concentration is obtained only after decoding by the device 13. In any case, the output value is a value corresponding to or corresponding to the exhaust gas mercury concentration.

  However, a mercury concentration meter that uses the single measured value itself at the time of measurement as an output value can output an output value at a high speed from the beginning of startup because a plurality of measured values are not averaged. For this reason, from the viewpoint of reducing the mercury concentration of the exhaust gas more quickly and effectively, in the exhaust gas mercury treatment system of the present invention, the mercury concentration is measured more than the mercury concentration meter whose output value is the average value of the mercury concentrations at a plurality of measurement points. It is desirable to use a mercury concentration meter that uses the single measured value itself at the time of the output as an output value.

The activated carbon supply device 12 will be described as an example in which the activated carbon supply capacity is 800 mg / Nm ³ . In addition, the activated carbon supply device 12 can change the supply amount of activated carbon in multiple stages. Here, an example of five stages is shown. Specifically, the activated carbon supply device 12 sets the supply amount (40 mg / Nm ³ ) of 5% of the maximum supply capacity to the predetermined amount A0, and sets the supply amount (200 mg / Nm ³ ) of 25% of the maximum supply capacity to the first amount. The supply amount A1, 50% of the maximum supply capacity (400 mg / Nm ³ ) is the second supply amount A2, and 75% of the maximum supply capacity (600 mg / Nm ³ ) is the third supply amount A3. It is possible to change the supply amount in five stages by setting the supply amount (800 mg / Nm ³ ) of 100% of the maximum supply capacity as the fourth supply amount A4.

Next, the control of the refuse treatment plant 1 (exhaust gas mercury treatment system) will be described in detail with reference to FIG.
First, when the operation of the waste treatment plant 1 is started, the control device 13 controls the activated carbon supply device 12 to intermittently supply a predetermined amount A0 of activated carbon into the pipe 9a at predetermined time intervals (step S1). ). Here, as an example, the activated carbon is intermittently supplied at intervals of 5 minutes. In other words, the supply of the activated carbon and the stop of the supply of the activated carbon are alternately repeated every five minutes.
The reason why a small amount of activated carbon is intermittently supplied is to remove dioxins and the like in addition to mercury by the dust collector 7.

  The control device 13 continuously receives output values transmitted by the mercury concentration meter 11 at predetermined intervals (for example, at intervals of 20 seconds), and the received output value is less than the first threshold C1 or the first threshold C1. It is determined whether or not this is the case (step S2). When the received output value is less than the first threshold value C1, the control device 13 continues the execution of step S1, that is, the intermittent supply of the activated carbon. If the received output value is equal to or greater than the first threshold value C1, as described later, the control device 13 increases the supply amount of the activated carbon from the predetermined amount A0 in accordance with the speed of change of the output value, and The control to supply the activated carbon continuously instead of the target is started.

The control device 13 calculates the speed of change of the output value each time a new output value is received. The speed can be calculated by dividing the difference between the new output value and the output value received immediately before (ie, the latest output value) by the predetermined interval of 20 seconds described above. That is,
(Speed of change of output value) = ((new output value) − (last output value)) / predetermined interval.
In addition, according to the revised Air Pollution Control Law enforced on April 1, 2018, the emission standard value of mercury in newly constructed waste incinerators is 30 μg / Nm ^{3 on} average per unit time. Therefore, here, the first threshold value C1 is set to a value corresponding to 20 μg / Nm ³ , for example, in order to lower the exhaust gas mercury concentration early from the stage of the exhaust gas mercury concentration slightly smaller than the legal reference value. .

Next, the case where the output value received by the control device 13 is equal to or more than the first threshold value C1 in step S2 will be described.
First, the control device 13 calculates the speed of change of the output value (rising speed) using the received new output value, and determines whether the rising speed is less than the first rising speed V1 (step S31) or not. Whether the speed is equal to or higher than the speed V1 and lower than the second speed V2 (step S32), the speed is higher than the second speed V2 and lower than the third speed V3 (step S33), or higher than the third speed V3 (step S34). Is determined. Here, as an example, the first rising speed V1 is a value corresponding to 1 μg / Nm ³ · s, the second rising speed V2 is a value corresponding to ³ μg / Nm ³ · s, and the third rising speed V3 is 5 μg. / Nm ³ · s.

When the rising speed is lower than the first rising speed V1, the control device 13 controls the activated carbon supply device 12 to continuously supply the activated carbon of the first supply amount A1 (step S41). When the rising speed is equal to or higher than the first rising speed V1 and lower than the second rising speed V2, the activated carbon having the second supply amount A2 is continuously supplied (Step S42). When the rising speed is equal to or higher than the second rising speed V2 and lower than the third rising speed V3, the activated carbon having the third supply amount A3 is continuously supplied (Step S43). When the rising speed is equal to or higher than the third rising speed V3, the activated carbon having the fourth supply amount A4 is continuously supplied (Step S44).
That is, when the output value is equal to or more than the first threshold value C1, the supply amount of the activated carbon is immediately greatly increased when the rising rate of the mercury concentration of the exhaust gas is rapidly increased, and when the rising rate is gradually increased. Can be increased slightly.

  Next, after execution of step S41, S42, S43, or S44, the control device 13 receives a new output value from the mercury concentration meter 11. Then, as described above, the control device 13 calculates the rising speed and determines whether the rising speed is less than 0 or more than 0. In FIG. 2, the determination performed after step S41 is performed at step S51, the determination performed after step S42 is performed at step S52, the determination performed after step S43 is performed at step S53, and the determination performed after step S44 is performed at step S53. It is set to S54.

  When it is determined in step S51 that the rising speed is 0 or more, the exhaust gas mercury concentration is increasing (during the rising) or is in a state of being balanced with the activated carbon supply amount. In order to reduce the mercury concentration in the exhaust gas early, it is necessary to further increase the supply amount of the activated carbon supplied at the present time, but it is increased gradually in consideration of economic efficiency. Therefore, control device 13 executes step S42. That is, the control device 13 controls the activated carbon supply device 12 to supply the second supply amount A2, which is a supply amount one step higher than the first supply amount A1.

Similarly, if it is determined in step S52 that the rising speed is 0 or more, the control device 13 executes step S43 because the mercury concentration of the exhaust gas is increasing (during the increase) or in a state in which the amount of activated carbon is balanced. I do. That is, the control device 13 controls the activated carbon supply device 12 to supply the third supply amount A3 which is a supply amount one stage higher than the second supply amount A2. If it is determined in step S53 that the rising speed is equal to or higher than 0, the control device 13 executes step S44. That is, the control device 13 controls the activated carbon supply device 12 to supply the fourth supply amount A4 which is a supply amount one step higher than the third supply amount A3.
However, when it is determined in step S54 that the rising speed is equal to or higher than 0, the mercury concentration of the exhaust gas is increasing (during the rising) or is in a state of being balanced with the activated carbon supply amount. Since the amount is the fourth supply amount A4, which is the maximum supply amount of the activated carbon supply device 12, the control device 13 continues with step S44.

  When it is determined in step S51, S52, S53, or S54 that the rising speed is less than 0, the exhaust gas mercury concentration is decreasing (descent). Then, the control device 13 determines whether the received output value is less than the second threshold C2 or not less than the second threshold C2. In FIG. 2, the determination performed after step S51 is performed in step S61, the determination performed after step S52 is performed in step S62, the determination performed after step S53 is performed in step S63, and the determination performed after step S54 is performed in step S61. S64.

Here, the second threshold value C2 is, for example, a value corresponding to a legal reference value, and corresponds to 30 μg / Nm ³ (unit time average value), which is a reference value of mercury in a newly installed waste incinerator. Is set to a value.
If it is determined in step S61, S62, S63, or S64 that the value is equal to or greater than the second threshold value C2, the mercury concentration of the exhaust gas is falling, but if it continues for a long time, it may exceed the reference value. For this reason, if the supply amount of the activated carbon is reduced at this point, it is difficult to quickly reduce the mercury concentration in the exhaust gas even during the descent.

  Therefore, the control device 13 controls the activated carbon supply device 12 to maintain the supply amount of the activated carbon currently being supplied. That is, when it is determined in step S61 that the value is equal to or larger than the second threshold value C2, the control device 13 continues step S41. Similarly, when it is determined in step S62 that the value is equal to or larger than the second threshold value C2, the control device 13 continues with step S42. If it is determined in step S63 that the value is equal to or larger than the second threshold value C2, the control device 13 continues with step S43. If it is determined in step S64 that the value is equal to or larger than the second threshold value C2, the control device 13 continues with step S44.

  If it is determined in step S61, S62, S63, or S64 that it is less than the second threshold value C2, the exhaust gas mercury concentration is falling, and the exhaust gas mercury concentration has already fallen below the legal reference value. Therefore, the control device 13 gradually reduces the supply amount of the activated carbon currently being supplied in consideration of economic efficiency.

  That is, when it is determined in step S64 that the value is less than the second threshold value C2, the control device 13 executes step S74. In step S74, the control device 13 controls the activated carbon supply device 12 to supply the third supply amount A3 which is a supply amount one stage lower than the fourth supply amount A4. At this time, the control device 13 has received a new output value from the mercury concentration meter 11, and determines whether the rising speed is less than 0 or 0 or more. When it is determined that the rising speed is 0 or more, the control device 13 performs step S44 in order to return to the fourth supply amount A4, which is the original supply amount of activated carbon, since the exhaust gas mercury concentration may increase again. Execute. On the other hand, when it is determined that the rising speed is less than 0, the control device 13 executes Step S63 because the mercury concentration of the exhaust gas is continuously decreasing.

  Similarly, if it is determined in step S63 that it is less than the second threshold value C2, the control device 13 executes step S73. In step S73, the control device 13 controls the activated carbon supply device 12 to supply the second supply amount A2, which is a supply amount one stage lower than the third supply amount A3. At this time, the control device 13 has received a new output value from the mercury concentration meter 11, and determines whether the rising speed is less than 0 or 0 or more. If it is determined that the rising speed is equal to or higher than 0, since the exhaust gas mercury concentration may increase again, the control device 13 performs step S43 to return to the third supply amount A3 which is the original supply amount of activated carbon. Execute. On the other hand, when it is determined that the rising speed is less than 0, the control device 13 executes Step S62 because the mercury concentration of the exhaust gas is continuously decreasing.

  If it is determined in step S62 that the value is less than the second threshold value C2, the control device 13 executes step S72. In step S72, the control device 13 controls the activated carbon supply device 12 to supply the first supply amount A1, which is a supply amount one stage lower than the second supply amount A2. At this time, the control device 13 has received a new output value from the mercury concentration meter 11, and determines whether the rising speed is less than 0 or 0 or more. When it is determined that the rising speed is equal to or higher than 0, since the exhaust gas mercury concentration may increase again, the control device 13 performs step S42 in order to return to the second supply amount A2 which is the original supply amount of activated carbon. Execute. On the other hand, when it is determined that the rising speed is less than 0, the control device 13 executes step S61 because the exhaust gas mercury concentration is continuously decreasing.

  Further, when it is determined in step S61 that the latest output value is less than the second threshold value C2, the control device 13 executes step S71. At this point, the minimum first supply amount A1 is supplied as the amount of continuously supplied activated carbon. Therefore, in order to further reduce the amount of activated carbon to be supplied, the control device 13 needs to determine whether or not to execute S1 for intermittent supply.

Therefore, after the execution of S61, the control device 13 determines whether the latest output value is less than the third threshold value C3 or more than the third threshold value C3. Here, the third threshold C3 is set to a value corresponding to 10 μg / Nm ³ smaller than the first threshold C1. That is, the third threshold value C3 is a value at which the exhaust gas mercury concentration at this point is sufficiently smaller than the legal reference value and smaller than a value corresponding to the first threshold value C1 at which continuous supply of activated carbon is started. I have.

If it is determined in step S71 that the value is less than the third threshold value C3, the control device 13 executes step S1. In this case, the mercury concentration of the exhaust gas is significantly lower than the reference value, and in consideration of economy, the control is returned to the normal control that does not require increasing the supply amount of the activated carbon.
If it is determined in step S71 that the value is equal to or larger than the third threshold value C3, the control device 13 executes step S31. Then, it is confirmed again whether there is any sign of an increase in the mercury concentration of the exhaust gas.

  According to the above-described embodiment, whether the mercury concentration in the exhaust gas flowing through the measurement location of the mercury concentration meter 11 rapidly increases, levels off, or decreases after the measurement of the mercury concentration 11, 11, the supply amount of the activated carbon supplied upstream of the dust collecting device 7 is significantly increased, gently increased, maintained, or decreased in accordance with the speed. be able to. In other words, since the appropriate amount of activated carbon is supplied in advance by predicting the change in mercury concentration at the activated carbon supply location, the amount of mercury in the exhaust gas discharged to the atmosphere can be reduced economically and effectively. be able to.

  Further, in the present embodiment, when the rising speed increases rapidly, the supply amount of the activated carbon can be greatly increased in advance, and when the rising speed is gradual, it can be increased in advance and stepwise. Once the activated carbon is increased and supplied, if there is a rising speed of 0 or more, the activated carbon is further increased and supplied. That is, since the amount of activated carbon is increased and supplied in multiple stages in accordance with the rising speed of the mercury concentration in the exhaust gas, the amount of mercury in the exhaust gas can be reduced more economically and effectively.

  Further, in the present embodiment, the activated carbon supply amount at that time is maintained until the exhaust gas mercury concentration falls below a predetermined value (a second threshold, for example, a legal reference value) regardless of the descending speed of the exhaust gas mercury concentration. And rapidly reduce the mercury concentration in the exhaust gas. If it is less than the predetermined value, the amount of activated carbon is reduced and supplied according to the rate of decrease of the mercury concentration in the exhaust gas. For this reason, the exhaust gas mercury concentration can be rapidly reduced, and if the concentration is less than the predetermined value, the amount of activated carbon is reduced in accordance with the decreasing speed of the exhaust gas mercury concentration, and finally the activated carbon is intermittently supplied. It is possible to reduce the amount of mercury emitted from exhaust gas more economically and effectively.

  In the present embodiment, the activated carbon may be a halogen-impregnated activated carbon. Halogen-impregnated activated carbon can obtain more stable and high mercury removal performance than ordinary activated carbon.

[Modification 1]
Hereinafter, a modification of the embodiment of the present invention will be described in detail with reference to the drawings. In the first modification, differences from the above-described embodiment will be mainly described, and description of the same portions will be omitted.
As shown in FIG. 3, the exhaust gas mercury removal system 1B of the present modification is characterized in that the control device 13B controls not only the activated carbon supply device 12 but also the cooling tower 6.

When the output value of the mercury concentration meter 11 becomes equal to or more than the first threshold value C1, the control device 13B of the present modification controls the cooling tower 6 to increase the amount of water to be sprayed. The temperature of the exhaust gas E that enters is lower than usual. However, the temperature shall be such that low temperature corrosion does not occur.
Since the amount of mercury removed increases when the temperature of the exhaust gas E is low, the first modification can reduce the amount of mercury in the exhaust gas more economically and effectively.

[Modification 2]
Hereinafter, a modification of the embodiment of the present invention will be described in detail with reference to the drawings. In the second modification, differences from the above-described embodiment will be mainly described, and description of the same portions will be omitted.
As shown in FIG. 4, an exhaust gas mercury removal system 1 </ b> C according to the present modification is characterized by including a fly ash circulation device 27.

The fly ash circulating device 27 is configured to transport the fly ash discharged from the bottom of the dust collecting device 7 by the backwashing of the dust collecting device 7 and the transported fly ash upstream of the dust collecting device 7 and And an ejection section 29 for ejecting (injecting) into the pipe 9a downstream of the cooling tower 6 and supplying the same.
According to the second modification, the unreacted activated carbon contained in the fly ash discharged from the dust collecting device 7 can be reused, so that the supply amount of new activated carbon can be reduced, and more economically. In addition, the amount of mercury in exhaust gas can be reduced.

  As described above, the embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to the embodiments, and includes design changes and the like without departing from the gist of the present invention. . For example, the exhaust gas mercury treatment system of the embodiment may have both the features of the first and second modifications.

1, 1B, 1C waste treatment plant (exhaust gas mercury removal system)
Reference Signs List 3 refuse incinerator 4 boiler 6 cooling tower 7 dust collector 8 chimney 9a pipe 9b pipe 11 mercury concentration meter 12 activated carbon supply device 13, 13B control device 14 hopper 15 feeder 28 transfer unit 29 ejection part E exhaust gas

The exhaust gas mercury removal system of the present invention measures the concentration of the mercury contained in the exhaust gas discharged from the dust collector that removes the mercury-containing exhaust gas, and outputs an output value corresponding to the measurement result. A concentration meter, an activated carbon supply device that supplies activated carbon to the exhaust gas upstream of the dust collector, and a control device that controls the activated carbon supply device based on the output value, wherein the control device includes: When the output value is less than the first threshold, the activated carbon supply device is controlled so as to supply a predetermined amount of the activated carbon, and the output value is equal to or more than the first threshold, and the rising speed of the output value is equal to the first value. If the rising speed of the output value becomes 0 or more after supplying the activated carbon of the first supply amount greater than the predetermined amount and supplying the activated carbon of the first supply amount, , The first supply amount Controls more second said activated carbon supply device to supply the activated carbon supply amount of Ri, after supplying the activated carbon of the second feed amount, when the rate of increase of the output value becomes 0 or more, wherein The activated carbon supply device is controlled so as to supply a third supply amount of the activated carbon that is larger than the second supply amount, and the output value is equal to or greater than the first threshold value, and the output value is increased at the first rate. If the rising speed is less than the second rising speed and less than the second rising speed, the activated carbon supply device is controlled to supply the activated carbon of the second supply amount, and the output value is equal to or more than the first threshold value, and the output When the rising speed of the value is equal to or higher than the second rising speed and less than the third rising speed, the activated carbon supply device is controlled to supply the activated carbon of the third supply amount, the first supply amount , Previous pre Symbol second supply amount or the third feed amount After supplying the activated carbon, if the rate of increase of the output value is less than 0, until the output value is less than the second threshold larger than the first threshold, maintain the supply amount of the activated carbon at that time, When the output value is less than the second threshold, the supply amount of the activated carbon at the time is reduced, and when the output value is less than a third threshold smaller than the first threshold, the predetermined amount is reduced. The activated carbon supply device is controlled to supply the activated carbon.

The exhaust gas mercury removal system of the present invention measures the concentration of the mercury contained in the exhaust gas discharged from the dust collector that removes the mercury-containing exhaust gas, and outputs an output value corresponding to the measurement result. A concentration meter, an activated carbon supply device that supplies activated carbon to the exhaust gas upstream of the dust collector, and a control device that controls the activated carbon supply device based on the output value, wherein the control device includes: When the output value is less than the first threshold, the activated carbon supply device is controlled so as to supply a predetermined amount of the activated carbon, and the output value is equal to or more than the first threshold, and the rising speed of the output value is equal to the first value. If the rising speed of the output value becomes 0 or more after supplying the activated carbon of the first supply amount greater than the predetermined amount and supplying the activated carbon of the first supply amount, , The first supply amount Controlling the activated carbon supply device to supply a larger second supply amount of the activated carbon, the output value is equal to or more than the first threshold, and the output value is increasing at a rate equal to or greater than the first increasing rate. If less than the second ascent rate, after controlling the activated carbon supply device to supply the activated carbon of the second supply amount, after supplying the activated carbon of the first supply amount or the second supply amount When the rising speed of the output value is less than 0, the supply value of the activated carbon at that time is maintained until the output value becomes less than a second threshold value larger than the first threshold value, and the output value is When the value is less than a second threshold, the supply amount of the activated carbon at the time is reduced, and when the output value is less than a third threshold smaller than the first threshold, the predetermined amount of the activated carbon is supplied. controlling the activated carbon supply device to, prior The dust collecting device is a bag filter, a refuse incinerator, a cooling tower disposed downstream of the refuse incinerator, and upstream of the bag filter, and fly ash discharged from the bag filter, Upstream of the bag filter, and a fly ash circulating device that is conveyed downstream of the cooling tower and supplied to the exhaust gas, further comprising an unreacted activated carbon contained in the fly ash in the exhaust gas. It may be used for lowering the mercury emission.

Claims (5)

A mercury concentration meter that measures the concentration of the mercury contained in the exhaust gas discharged from the dust collector that removes the exhaust gas containing mercury, and outputs an output value corresponding to the result of the measurement;
An activated carbon supply device for supplying activated carbon to the exhaust gas upstream of the dust collector,
A control device that controls the activated carbon supply device based on the output value,
The control device, when the output value is less than a first threshold, controls the activated carbon supply device to supply a predetermined amount of the activated carbon,
When the output value is equal to or more than the first threshold, and the rising speed of the output value is less than the first rising speed, the activated carbon is supplied at a first supply amount greater than the predetermined amount, and the first carbon is supplied. After supplying the supply amount of the activated carbon, if the rate of increase of the output value becomes 0 or more, the activated carbon supply device is controlled to supply the second supply amount of the activated carbon which is larger than the first supply amount. ,
When the output value is equal to or higher than the first threshold, and the rising speed of the output value is equal to or higher than the first rising speed and lower than a second rising speed, the activated carbon is supplied in the second supply amount. Controlling the activated carbon supply device,
After supplying the activated carbon of the first supply amount or the second supply amount, if the rising speed of the output value is less than 0, the output value is less than the second threshold larger than the first threshold. Until becomes, maintain the supply amount of the activated carbon at that time, if the output value is less than the second threshold, reduce the supply amount of the activated carbon at the time, the output value is the first An exhaust gas mercury removal system, wherein the activated carbon supply device is controlled so as to supply the activated carbon in the predetermined amount when the value becomes smaller than a third threshold smaller than the threshold.   The exhaust gas mercury removal system according to claim 1, wherein the result of the measurement is the concentration of the mercury at the time of the measurement.   The exhaust gas mercury removal system according to claim 1 or 2, wherein the activated carbon is a halogen-impregnated activated carbon. Garbage incinerator,
Further comprising a cooling tower located downstream of the incinerator and upstream of the dust collector,
The dust collector is a bag filter,
The exhaust gas is discharged from the refuse incinerator,
4. The control device according to claim 1, wherein, when the output value is equal to or more than the first threshold, the control device controls the cooling tower to reduce the temperature of the exhaust gas. 5. 2. An exhaust gas mercury removal system according to item 1. The dust collector is a bag filter,
Garbage incinerator,
A cooling tower disposed downstream of the incinerator and upstream of the bag filter;
Fly ash discharged from the bag filter, upstream of the bag filter, and, further comprising a fly ash circulator for transporting downstream of the temperature reducing tower and supplying the exhaust gas,
The exhaust gas mercury removal system according to any one of claims 1 to 3, wherein unreacted activated carbon contained in the fly ash is used to reduce the amount of the mercury in the exhaust gas.

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