JP3027127B2 - Operation control device for garbage incineration equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refuse incineration system for operating an incinerator while removing so-called pollutants contained in incineration exhaust gas when incinerating general waste and industrial waste. It relates to an operation control device.

[0002]

2. Description of the Related Art Exhaust gas from municipal waste incinerators includes not only carbon dioxide, water vapor and oxygen but also soot and dust, which are controlled substances.
It contains hydrogen chloride (HCl), sulfur oxides (SOx), nitrogen oxides (NOx), and the like. The emission concentration and total amount of these regulated substances are regulated by the Air Pollution Control Law and the like. Exhaust gas and dust also contain trace amounts of heavy metals such as cadmium, chrome, and mercury. Recently, hydrogen fluoride (HF)
Trace contaminants such as dioxins and dioxins are also a problem.

The Ministry of Health and Welfare has established "Guidelines for Prevention of Dioxin Generation Related to Waste Disposal" from the viewpoint that it is desirable to minimize the emission of dioxins into the environment. In order to control the generation and emission of dioxin from garbage incineration facilities in accordance with these guidelines, neutralizing substances should be added according to the amount of dioxin generated, and the combustion temperature (Temp
erature), combustion time (Time), eddy current conditions during combustion (Tu
rbulence).

[0004] In order to suppress the generation of dioxin, it is necessary to measure the amount of dioxin generated and to grasp the state of generation. However, since the amount of dioxin in the exhaust gas released to the atmosphere is very small, it is difficult to measure dioxin, and an extremely expensive analyzer is required. For this reason, for example, Japanese Unexamined Patent Publication No.
As in the invention described in Japanese Patent Publication No. 9-29, the measurement is performed using dioxin precursors such as chlorobenzene and chlorophenol as substitute indexes.

[0005]

However, in the above-mentioned Japanese Patent Application Laid-Open No. H4-181649, exhaust gas is collected from a flue of a garbage incineration facility, and after the collection is completed, a chlorobenzene group capturing tube is removed from the collecting device. Since the measurement operation is performed by the gas chromatograph, a considerable time is required until the measurement result is reflected in the operation state of the refuse incinerator.

In order to promptly reflect the measurement results, it is necessary to continuously measure the components in the exhaust gas.
As a semi-continuous measurement and monitoring device for chlorobenzenes
There is an invention described in JP-A-321796. However, this semi-continuous monitoring device does not directly measure dioxins, but instead uses a sample gas from which co-existing moisture and dust have been removed by pretreatment to measure chlorobenzene as a substitute substance. In addition, there is a possibility that the measurement result may not be promptly and accurately reflected on the operating state of the incinerator.

Accordingly, the present invention removes pollutants in exhaust gas by almost continuously measuring and monitoring the exhaust gas of the incinerator and immediately reflecting the measurement result in the operating state of the incinerator. It is an object of the present invention to provide an operation control device for a waste incineration plant.

[0008]

According to a first aspect of the present invention, there is provided an operation control device for a refuse incineration plant connected to an outlet of a refuse incinerator.
And a post-treatment means for incineration exhaust gas is provided.
Waste incineration facility that emits incineration exhaust gas that has passed through
Incineration exhaust gas from near the garbage incinerator outlet.
First analysis for introducing and analyzing the composition of the incineration exhaust gas
Means and incineration up to the chimney of said aftertreatment means
Exhaust gas is introduced to analyze the composition of the incinerated exhaust gas
Second analysis means, and an analysis signal by the first analysis means
Control means for processing the data and outputting a control signal;
Upon receiving a control signal from the stage, a predetermined neutralizing substance is
A neutralizing substance supply means for supplying to the incinerator;
Receiving these control signals, the combustion temperature and combustion time of the incinerator,
Changing at least one of the eddy current conditions during combustion
Operation adjustment means for adjusting the operation state of the furnace,
The amount of components contained in the incineration exhaust gas based on the control signal
The neutralizing substance is supplied in an amount corresponding to
And adjusting the operating state of the incinerator by the operation adjusting means.
And the incineration exhaust gas released to the atmosphere by the second analysis means.
It is characterized by monitoring the composition of steel .

[0009] The composition of the incineration exhaust gas near the outlet of the refuse incinerator is measured by the first analysis means, and when an analysis signal relating to the measurement result is sent to the control means, the control means sets a predetermined value. A neutralizing substance for the above-mentioned components is selected and the input amount is calculated, or a control signal for instructing these regarding the change of the combustion temperature, the combustion time, and the vortex condition is operated with the neutralizing substance supply means. To the adjusting means. The neutralizing substance supply means inputs the neutralizing substance specified by the control signal into the incinerator, and the operation adjusting means changes the combustion temperature in the incinerator. For this reason, the pollutants in the measured exhaust gas are neutralized or the production state is changed by changing the operation state, and the emission of the pollutants is suppressed.

[0010] The concentration of the components in the incineration exhaust gas near the outlet of the refuse incinerator is relatively high for all components. For this reason, the component analysis in the exhaust gas can be easily performed as compared with the case where the concentration is low. In particular, dioxins are in a sufficiently measurable concentration because the exhaust gas is before passing through the post-processing means, and the dioxins can be directly measured without using a substitute substance.

In order to use incinerated exhaust gas having a high component concentration for measurement, continuous measurement can be performed, and the state of the exhaust gas can be constantly monitored.

Moreover, since the measurement is performed in the vicinity of the outlet of the incinerator, it is possible to promptly make a judgment for charging the neutralizing substance and adjusting the operation of the incinerator, and to quickly reflect the measurement result in the operating state of the incinerator. Thus, even when the incinerated substance is changed, the emission of pollutants can be quickly suppressed.

[0013]

[0014]

[0015]

[0016] incineration exhaust gas discharged from the incinerator, after
Contaminants are removed by passing through post-processing means such as a continuous dust collector, and the emission concentration of the contained pollutants etc.
Etc. are suppressed below the regulation value, and are released from the chimney to the atmosphere. Since the exhaust gas is collected from the flue up to the chimney and analyzed for its composition by the second analysis means, it is always necessary to monitor the composition of the exhaust gas before it is released to the atmosphere.
I can do it.

The result of the analysis by the second analysis means is sent to a display means for display or printed by a plotter or the like. Further, the analysis signal is sent to the control means, and similarly to the analysis signal by the first analysis means, the control signal of the neutralizing substance supply means and the operation adjustment means is sent to change the operating state of the incinerator. Or for the supply of neutralizing substances.

Further, for the purpose of enabling the exhaust gas to be measured before the chimney by the first analyzing means, and aiming at miniaturization of the equipment, the operation control device of the refuse incineration equipment according to claim 2 is A post-processing means for the incineration exhaust gas is provided continuously at the outlet of the refuse incinerator, and the composition analysis of the incineration exhaust gas is performed in a refuse incineration facility for discharging the incineration exhaust gas passed through the post-processing means to the atmosphere. Analyzing means, controlling means for processing a signal analyzed by the analyzing means and outputting a control signal, and receiving a control signal from the controlling means and supplying a predetermined neutralizing substance to the refuse incinerator Operation adjusting means for adjusting the operating state of the combustion furnace by changing at least one of the combustion temperature and the combustion time of the incinerator and the vortex conditions during combustion in response to the control signal from the supply means and the control means. A first pipe for introducing incineration exhaust gas from the vicinity of the outlet of the refuse incinerator to the analysis means, and a second pipe for introducing incineration exhaust gas from the vicinity of the chimney of the post-processing means to the analysis means. And a pipeline switching means for switching the first pipeline and the second pipeline at predetermined time intervals, according to an analysis result of the incineration exhaust gas introduced through the first pipeline. Based on the control signal, an amount of neutralizing substance corresponding to the amount of the component contained in the incineration exhaust gas is supplied by the neutralizing substance supply means, and the operating state of the incinerator is adjusted by the operation adjusting means, The composition of the incineration exhaust gas released to the atmosphere is monitored based on the analysis result of the incineration exhaust gas introduced through the second conduit.

A display means, a plotter or the like is connected to the control means to display or print an analysis result of exhaust gas collected in front of the chimney. The measurement result of the exhaust gas collected at the refuse incinerator outlet can also be displayed or printed.

Moreover, if the cycle of switching the measurement position is adjusted in consideration of the time required for the incineration exhaust gas discharged from the incinerator to reach the front of the chimney, the charging of the neutralizing substance and the change of the operation state can be performed. Since the improved exhaust gas measurement can be performed after the change, the exhaust gas can be constantly monitored.

[0021]

[0022]

[0023]

[0024]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the configuration of a refuse incineration plant according to a preferred embodiment of the present invention.

FIG. 1 is a diagram showing a schematic configuration of a refuse incineration facility provided with an operation control device according to the present invention. The combustible refuse to be incinerated is put into the refuse incinerator 1 and burned. The incineration exhaust gas generated at the time of combustion in the refuse incinerator 1 is appropriately cooled through a heat exchanger 2 which is a post-processing means, and then sent to a dust collector 3 to remove soot and the like in the exhaust gas. Then, the air is supplied to the chimney 5 by the induction fan 4 and released to the atmosphere. The dust collection device 3
, A cyclone type dust collector, an electric dust collector, a bag filter and the like are installed alone or in an appropriate combination. Further, if necessary, in order to remove hydrogen chloride and sulfur oxides, which are pollutants, slaked lime is blown with powder in front of a dust collecting device, or a smoke washing device is installed.

From the inlet of the flue 6a for guiding the incineration exhaust gas from the refuse incinerator 1 to the heat exchanger 2, that is, from the measurement position A near the outlet of the refuse incinerator 1, via the sampling pipe 7a. Incineration exhaust gas has been sampled. The sampling pipe 7a communicates with an infrared spectroscopy analyzer 10 as an analysis means via a switching valve 11 as a pipe switching means. A return pipe 7b is connected to the measurement position A, and as shown in FIG. 2, the return pipe 7b communicates with the discharge side of the induction fan 7c. The suction side of the induction fan 7c is communicated with the sampling pipe 7a. It should be noted that a sample gas is supplied to the infrared spectroscopic analyzer 10 by operating the attracting fan 10a.

Exhaust gas is collected from the measurement position B of the flue 6b from the dust collecting device 3 to the chimney 5 via a collecting pipe 8a. The sampling pipe 8a communicates with the infrared spectroscopic analyzer 10 via the switching valve 11. A return pipe 8b is connected to the measurement position B.
8b, like the return pipe 7b, is connected to the discharge side of the induction fan 8c, and the suction side of the induction fan 8c is connected to the collection pipe 8a.
Is communicated on the way.

The output signal of the infrared spectrometer 10 is sent to the control means 12 as an analysis signal. This control means
At 12, based on the analysis signal, it is determined whether or not the concentration of the contaminant contained in the incineration exhaust gas is equal to or less than a predetermined value. A control signal including an instruction necessary for removing the water is sent to each of the neutralizing substance supplying means 13 and the operation adjusting means 14.

The neutralizing substance supply means 13 supplies the neutralizing substance to the refuse incinerator 1 according to the control signal. As the neutralizing substance, a known substance is used. FIG. 3 is a diagram showing a purification rate when ammonia (NH ₃ ) is used as a neutralizing substance of nitrogen oxides, and the horizontal axis shows the NH ₃ / NOx molar ratio. As shown in the figure, it is shown that the purification rate increases as the neutralizing substance increases. FIG. 5 shows the removal rate of hydrogen chloride and sulfur oxide from slaked lime, and the horizontal axis shows the equivalent ratio of slaked lime. As shown in the figure, when slaked lime as a neutralizing substance is increased, the removal rates of both hydrogen chloride and sulfur oxide increase. The removal rate of hydrogen chloride is saturated when the equivalent ratio is 1.0, and the removal rate remains flat even when the equivalent ratio increases.

The operation adjusting means 14 adjusts any one or all of the combustion temperature and the combustion time in the incinerator 1 in accordance with the control signal and any or all of the eddy current conditions during the combustion, and adjusts the operating state of the incinerator 1. Make adjustments. Regulating operating conditions in incinerators is known as a method for removing contaminants. FIG. 4 is a diagram showing the relationship between nitrogen oxides and the temperature of the upper part of the furnace. As the temperature increases, the generation of nitrogen oxides increases. On the other hand, FIG. 6 is a diagram showing the relationship between dioxin and the temperature in the upper part of the furnace. As the temperature rises, the amount of dioxin generated decreases. For this reason, in general, incineration is performed at about 900 to 1200 ° C. in an incinerator, and the incineration exhaust gas is rapidly cooled to about 200 ° C. or less by the heat exchanger 2. A measuring device or the like is provided in the incinerator for each of the burning temperature, the burning time, the eddy current condition, and the like of the incinerator, and a measurement signal of the measuring device is input to the control means 12.

The display means 15 is provided from the control means 12.
A display control signal is sent to the printing means 16 such as a plotter, and a switching command signal is sent to the switching valve 11, respectively. The display means 15 displays the result of the analysis by the infrared spectroscopic analyzer 10 on the display device, and the printing means 16 prints the result of the analysis on paper.

The operation of the embodiment of the operation control apparatus for a refuse incineration plant according to the present invention constituted as described above will be described below.

The garbage transported to the refuse incineration facility and collected for incineration is put into the refuse incinerator 1 by a predetermined amount and burned. The incineration exhaust gas generated at the time of combustion is exhausted from the flue 6a to the outside of the incinerator 1, sent to the heat exchanger 2, supplied to the preheating of the incineration air, and cooled to an appropriate temperature. Next, the contaminants fed to the dust collecting device 3 and remaining in the exhaust gas are removed.

The exhaust gas that has passed through the dust collecting device 3 is sucked by the induction fan 4 and guided to the chimney 5, rises inside the chimney 5, and is discharged into the atmosphere from a high place. The incineration exhaust gas is sucked by the induction fan 4 so as to pass through the heat exchanger 2 and the dust collection device 3 and is fed. However, an induction fan or a pushing fan is disposed at a required position in the flue. Make sure it is fed smoothly.

A collection pipe 7a is connected to the measurement position A, and the incineration exhaust gas at the measurement position A is collected from the collection pipe 7a by the attraction fan 7c. A return pipe 7b is connected to the discharge side of the attraction fan 7c, and its tip is at the measurement position A.
Measurement position A by the induction fan 7c.
Is circulated through the collection pipe 7a and the return pipe 7b. On the other hand, the exhaust gas at the measurement position B also circulates through the sampling pipe 8a and the return pipe 8b.

Then, the switching valve 11 is switched to change the sampling pipe.
7a is communicated with the infrared spectrometer 10, and the inducing fan 7c is stopped, and when the inducing fan 10a is operated, the incineration exhaust gas remaining in the collection pipe 7a and the return pipe 7b is removed by the infrared spectrometer. At 10, a composition analysis of the incineration exhaust gas at the measurement position A is performed. Further, if the sampling pipe 8a and the infrared spectroscopic analyzer 10 are communicated by switching the switching valve 11, the composition analysis of the exhaust gas at the measurement position B is performed.

The analysis result of the infrared spectrometer 10 is controlled by a control means.
Sent to 12. Concentration of the pollutants in incineration exhaust gas based on the analysis results of the control unit 12 determines whether less than a predetermined value, the neutralizing substance supply instructions required to remove the contaminants exceeds a predetermined value It is sent to the means 13 and the operation adjusting means 14.

For example, when the nitrogen oxide exceeds a predetermined value, an instruction to supply bromine (Br) or ammonia to the incinerator 1 is sent to the neutralizing substance supply means 13. And
The neutralizing material supply means 13 is operated, and the neutralizing material is injected into the incinerator 1. For example, when the amount of dioxin exceeds a predetermined value, an instruction to increase the furnace temperature is sent to the operation adjusting means 14, and the operation of the operation adjusting means 14 raises the combustion temperature.

The predetermined neutralizing substance for pollutants is, for example, bromine or ammonium for nitrogen oxides, and sodium hydroxide (NaO) for sulfur oxides.
H) and the like, but dioxin has calcium hydroxide (Ca
Calcium compounds such as (OH) ₂ ), calcium oxide (CaO) and calcium carbonate (CaCO ₃ ) or coke, and hydrogen chloride include slaked lime and calcium silicate hydrate. Further, in order to control dioxins, temperature, residence time, and mixing, that is, operating conditions such as combustion temperature and combustion time of the incinerator, vortex conditions during combustion are adjusted, and nitrogen oxides are reduced. For the suppression, a low oxygen operation or the like is performed. And the control means 12 appropriately combines the charging of the neutralizing substance and the change of the operating state,
Neutral substance supply means 13 and operation adjustment means 14 so that pollutants are removed under the optimum conditions for the waste incineration facility.
Will be instructed.

When the neutralizing substance is introduced, it reacts with the pollutants in the incineration exhaust gas in the incinerator 1 to neutralize the pollutants. Further, the operation state of the incinerator 1 is changed by the operation adjusting means. These operations will reduce or eliminate pollutants in the incineration exhaust gas.

When the switching valve 11 is switched to a position where the sampling pipe 8a and the infrared spectroscopic analyzer 10 are communicated, the measurement position B
The composition analysis of the exhaust gas at is performed.
At the measurement position B, the analysis is performed on the exhaust gas from which the pollutants have been removed, so that the pollutants are not contained in excess of the regulation value. For this reason, the measurement result at the measurement position B is only sent out from the control means 12 to the display means 15 and the printing means 16 so as to be displayed and printed, and it is not always necessary to reflect the result in the removal of contaminants. do not do.

However, since the exhaust gas that has passed through the measurement position B is released to the atmosphere, if pollutants are detected at this position B, the environment may be polluted. For this reason, when the measurement result at the measurement position B contains a contaminant that is equal to or greater than the regulation value, the control means 12 supplies the neutralizing substance to the neutralizing substance supply means 13 or the operation adjusting means 14 and supplies the neutralizing substance or operates A configuration may be adopted in which a control signal instructing a change of the state is transmitted.

The measurement at the measurement position A and the measurement at the measurement position B are switched and performed at predetermined intervals. This switching is performed by switching the switching valve 11. When the composition of the incineration exhaust gas is improved by the operation of the neutralizing substance supply means 13 and the operation adjustment means 14, a considerable time must elapse before the improved exhaust gas reaches the measurement position B. The measurement at the measurement position A is performed for a predetermined time ΔT sufficient for the improved exhaust gas to reach the position B, and the measurement is switched to the measurement at the measurement position B after the elapse of the time ΔT. Then, the measurement is switched to the measurement at the measurement position A after a lapse of a predetermined time. Note that the measurement at the measurement position B may be performed after a predetermined time ΔT elapses, and the measurement position may be switched every predetermined time ΔT.

The predetermined time ΔT is determined according to the moving speed and the flue distance according to the scale of each refuse incineration facility. In addition, the infrared gas spectrometer 10
If the length of the sampling pipes 7a and 8a is long, the exhaust gas before the improvement may stay even after the predetermined time ΔT has elapsed. Therefore, when performing composition analysis, it is necessary to exchange the retained exhaust gas with the improved exhaust gas. For this reason, the exhaust gas retained in the collection pipe and the return pipe was discharged by, for example, operating the attraction fan 10a for a certain period of time. Later, the improved exhaust gas is supplied to the infrared spectrometer 10. Therefore, it is desirable that the predetermined time ΔT be determined in consideration of the time required for ventilation at this time.

As described above, by performing measurement while switching the measurement position every predetermined ΔT time, continuous measurement can be performed even when the incineration exhaust gas is improved by the operation of the neutralizing material supply means 13 and the like. Therefore, it is possible to constantly monitor the incineration exhaust gas.

In this embodiment, the measurement positions A and B
Although the measurement is performed at two locations, the operation control of the incinerator for removing or reducing pollutants can be realized by performing the measurement at the measurement position A. No measurement is required.

[0047]

As described above, according to the operation control device for a refuse incineration plant according to the first aspect of the present invention, the composition of the incineration exhaust gas at the outlet of the refuse incinerator is analyzed.
A sample gas having a high component concentration can be used for analysis.
Therefore, the composition analysis can be easily performed, and the composition of the incineration exhaust gas can be continuously measured. Therefore, the measurement result can be reflected in the operation state of the refuse incinerator, and the contaminants can be quickly removed. In addition, since the exhaust gas is continuously measured, the amount of the neutralizing substance to be introduced can always be controlled to an appropriate amount, the cost of the neutralizing substance can be reduced as much as possible, and the reduction of pollutants in the exhaust gas can be reduced. Can be realized at cost.

Further, since the composition of the exhaust gas to be released to the atmosphere is analyzed, the exhaust gas released to the atmosphere can be monitored.

Further, according to the operation control device of the refuse incineration plant according to the second aspect of the present invention, the exhaust gas is analyzed by the one analyzing means for each of the incinerator outlet portion and before the exhaust gas is released to the atmosphere. Can be. Moreover, by switching the measurement position every predetermined time,
At any measurement position, the composition analysis of the exhaust gas can be performed continuously.

[0050]

[Brief description of the drawings]

FIG. 1 is a diagram showing a schematic configuration of an operation control device of a refuse incineration plant according to the present invention.

FIG. 2 is a diagram illustrating a configuration of a sampling unit for sampling a sample gas and providing the sample gas to an analysis unit.

FIG. 3 is a diagram showing a purification rate when ammonia is used as a neutralizing substance of nitrogen oxides.

FIG. 4 is a diagram showing the relationship between nitrogen oxides and the temperature of the upper part of the furnace.

FIG. 5 is a diagram showing the removal rates of hydrogen chloride and sulfur oxides from slaked lime.

FIG. 6 is a diagram showing the relationship between dioxin and the temperature in the upper part of the furnace.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Garbage incinerator 2 Heat exchanger 3 Dust collection device 4 Induction fan 5 Chimney 6a Flue 6b Flue 7a Sampling pipe 7b Return pipe 8a Sampling pipe 8b Return pipe 10 Infrared spectrometer (analysis means) 11 12) Control means 13 Neutral substance supply means 14 Operation adjustment means A Measurement position B Measurement position

Continuing from the front page (72) Inventor Takanori Shiina 1-4-1 Chuo, Wako-shi, Saitama Pref. Inside Honda R & D Co., Ltd. (72) Setsuo Kikuchi 1-4-1 Chuo, Wako-shi, Saitama Pref. Honda Technology Co., Ltd. Inside the research laboratory (72) Inventor Takanori Akakawa 1-4-1 Chuo, Wako-shi, Saitama Pref. Honda Research Institute, Ltd. (56) References JP-A-58-61181 (JP, A) JP-A-8-200658 (JP) (A) JP-A-3-267119 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) F23G 5/50 ZAB F23G 5/00 ZAB F23N 5/00

Claims (2)

(57) [Claims] 1. A refuse incineration facility which is provided with a post-treatment means for incineration exhaust gas continuously at an outlet of the refuse incinerator and discharges the incineration exhaust gas passed through the post-treatment means to the atmosphere. First analysis means for introducing the incineration exhaust gas from the vicinity of the outlet and analyzing the composition of the incineration exhaust gas; and analyzing the composition of the incineration exhaust gas by introducing the incineration exhaust gas up to the stack of the post-processing means. Second analyzing means for processing the analysis signal from the first analyzing means and outputting a control signal; receiving a control signal from the control means to remove a predetermined neutralizing substance from the refuse. Neutralizing substance supply means for supplying to the incinerator; receiving the control signal from the control means, changing at least one of a combustion temperature and a combustion time of the incinerator, and a vortex condition during combustion to operate the combustion furnace. Luck adjusting condition Adjusting means, based on the control signal, supplies an amount of neutralizing substance corresponding to the amount of the component contained in the incineration exhaust gas by the neutralizing substance supply means, the operation adjusting means of the incinerator An operation control device for a refuse incineration plant, wherein the operation state is adjusted, and the composition of the incineration exhaust gas released to the atmosphere is monitored by the second analysis means. 2. A refuse incineration facility, wherein post-treatment means for incineration exhaust gas is provided continuously at an outlet of the refuse incinerator, and the incineration exhaust gas passing through the post-treatment means is discharged to the atmosphere. Analysis means for performing a composition analysis of the following; control means for processing an analysis signal from the analysis means to output a control signal; receiving a control signal from the control means, and passing a predetermined neutralized substance to the refuse incinerator. Receiving the control signal from the control means, and adjusting at least one of the combustion temperature and the combustion time of the incinerator and the vortex condition during combustion to adjust the operation state of the combustion furnace Operation adjusting means, a first conduit for introducing incineration exhaust gas from the vicinity of the outlet of the refuse incinerator to the analysis means, and introducing the incineration exhaust gas up to the chimney of the post-processing means to the analysis means. Second And a pipe switching means for switching the first pipe and the second pipe at predetermined time intervals. The analysis result of the incineration exhaust gas introduced through the first pipe Based on the control signal according to the amount of neutralizing material corresponding to the amount of components contained in the incineration exhaust gas is supplied by the neutralizing material supply means, the operating state of the incinerator by the operation adjustment means An operation control device for a refuse incineration plant, comprising adjusting and monitoring the composition of the incineration exhaust gas released to the atmosphere based on the analysis result of the incineration exhaust gas introduced through the second pipeline.