JPH06304495A - Monitor for state of dust in hopper of electric dust collector - Google Patents

Abstract

PURPOSE:To monitor combustion of embers of dust in the hopper of an elastic dust collector by providing an SOX gauge and/or a CO gauge respectively detecting SOX concentration and/or CO concentration of exhaust gas in the hopper of the electric dust collector provided in the flue of a combustion furnace and providing a recording device for recording a change of the detection value in the elapse of time. CONSTITUTION:A monitor for the state of dust in the hopper of an electric dust collector is provided with one or a plurality of pieces of SOX gauge and/or CO gauge 13 for detecting SOX concentration and/or CO concentration of exhaust gas in the hopper 19 of the electric dust collector 5 provided in the flue of a combustion furnace 1 and with a recording device 15 for recording a change of the detection value in the elapse of time. One or a plurality of pieces of temperature detectors 14 are provided which detect the temperature in the dust layer deposited in the hopper 19 of the electric dust collector 5. Furthermore, a data processor 15 is provided which pattern-recognizes a change of the detected value in the elapse of time in at least one selected from among the SOX concentration, the CO concentration and the temperature and compares the pattern-recognized change of the detected value in the elapse of time with threshold on the preset pattern recognition. In the case of reaching the value not less than the threshold, e.g. ANN is outputted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for monitoring a dust condition in an electrostatic precipitator hopper, which monitors in-place combustion of dust accumulated in a hopper of an electrostatic precipitator provided in a flue of a combustion furnace.

[0002]

2. Description of the Related Art In a combustion furnace such as a boiler that burns fuel oil or coal to generate steam, a dust collector such as an electric dust collector (hereinafter referred to as "EP") is installed in a flue as an environmental measure. The hopper installed at the bottom of this dust collector temporarily stores the fine dust particles, which are composed of ash and unburned matter, contained in the exhaust gas, and then the equipment is sent to the ash treatment device. .

FIGS. 3 to 5 show an outline of these conventional facilities, and FIG. 3 shows an example of a conventional dust collecting facility of a coal-fired power plant. In the dust collection equipment of a coal-fired power plant, what has been generally put into practical use is:
There are four types of high temperature EP, low temperature EP, low temperature EP with gas conditioning, and baghouse, and these four types are also shown in FIG. 4 shows an example of a conventional coal-fired ash processing apparatus, and FIG. 5 shows an example of a conventional heavy-duty thermal ash processing apparatus.

The structure of the EP used in these devices is shown in FIGS. 6, 7 and 8 each show an example of the structure of a conventional EP. Referring to the figure, a plurality of hoppers are provided in the lower part of the EP, and after temporarily storing dust in the hoppers, the ash treatment equipment shown in FIGS. Send by air transportation.

The properties of the dust collected by the EP as described above are generally as follows.

(1) In the case of a fuel oil burning boiler, the heating value is generally 2500 to 6500 Kcal / kg, the exhaust gas temperature is 130 to 150 ° C., and is not controlled by the properties of the fuel oil used, especially the residual carbon content. Fuel carbon content 40-90wt%, ammonium sulfate content 5-5
It is 0 wt%, ash content is 10 wt% or less, and water content is almost 0%.

(2) In the case of pulverized coal burning boiler The ash content of the coal used, the fuel ratio (fixed carbon / volatile content), the particle size of the fine powder, the furnace residence time, etc. When charcoal is used, it may reach 5 to 15%, and when starting the boiler, heavy oil ash may be included because light oil or heavy oil is used as the starting fuel. The exhaust gas temperature is about 130 to 150 ° C, which is the same as the fuel oil fired boiler.

As is clear from the above description, the dust stored in the hopper is a combustible substance having a calorific value by itself, and its temperature reaches 100 ° C. or higher, but it also has the following characteristics. .

(1) The dust itself collected by the EP is a combustible substance, and even if the calories are high, it is the burnt residue of the fuel that has passed through the high temperature furnace, and the volatile matter that is a factor for lowering the ignition temperature is It is hardly included. That is,
Dust has the characteristic of having a high ignition temperature.

(2) Oxygen concentration in ash during normal operation is low (for example, about 4 to 10%), so that the oxidation reaction is slow and spontaneous ignition is difficult.

(3) As described above, conventionally, the dust in the hopper is intermittently extracted and sent to the ash processing device.
The time spent in the hopper is relatively short. Therefore, the dust has the characteristic that the temperature rise due to natural oxidation in the hopper is small.

As described above, since the dust in the hopper has a high ignition temperature, it is difficult to spontaneously ignite, and the temperature rise due to natural oxidation is small. Therefore, when the number of starting and stopping of the combustion furnace is relatively small as in the conventional case, Although it was a combustible material, there was little need to consider the problem of set-up combustion in the hopper.

[0013]

However, in recent years, the number of times of starting and stopping the combustion furnace is increasing.

That is, in a conventional combustion furnace, for example, a boiler for power generation, there is a large difference in power supply and demand between summer and winter and spring and autumn, weekday and weekend, daytime and nighttime, and stabilization of operation in a nuclear power generation boiler. There is also a need for, and a daily start-stop type of operation is used in which start and stop are intense.

Also in the industrial boiler, the number of holidays is increasing due to the trend of shortening working hours in recent years, so that the opportunity to stop the boiler is increasing because the ventilation of the factory is unnecessary.

As described above, when the number of times the combustion furnace is started and stopped increases, the following problems become serious.

(1) Even if the fuel oil is burned for both starting and stopping, the amount of fuel is small when the boiler is started and stopped, and the combustion air temperature and the boiler water temperature are low, so the ambient temperature in the furnace is low. Also, since the temperature of the combustion air is low, the unburned matter generated by combustion is dust containing highly volatile components, and some of the dust is collected and collected. , Decrease the dust ignition temperature (and the ash temperature is high). By the way, Figures 8 and 9 show THC (Total Hydro Carbon) of the unburned components in the flue when the startup is stopped.
The result measured by the meter is shown.

(2) The oxygen concentration in the exhaust gas of the flue is high at the time of starting and stopping, and about 21% before starting and after stopping, which is about the same as the outside air. That is, the exhaust gas having a high oxygen concentration flows into the hopper when the combustion furnace is started and stopped.

(3) When the combustion furnace is stopped, the ash processing device is also stopped or stopped, and dust is often left in the hopper for 1 to several days while the can is stopped. As the number of times the combustion furnace is started and stopped increases, the chances that the dust is left in the hopper for a while will increase.

Therefore, as the number of times the combustion furnace is started and stopped increases, the chances that dust having a low ignition temperature will be left in the hopper in a high oxygen atmosphere for a long time increases. As a result, the carbon content in the dust is naturally oxidized, the temperature of the dust itself rises, and the dust is ignited, which increases the risk of causing the hopper to become red-hot by the in-place combustion. Then, the red heat of the hopper causes a failure of the ash processing equipment and the like, leading to an accident of stopping the combustion furnace unit. Moreover, while the number of hoppers to be installed is increasing with the recent increase in the size of plants, the number of workers engaged in the work is small, so it is necessary to keep a close eye on the dust condition in the hopper. It cannot be said that

[0021] It is an object of the present invention to provide a dust condition monitoring device in an electrostatic precipitator hopper which is capable of monitoring the burning and burning of dust in the hopper and preventing accidents due to red heat of the hopper.

[0022]

The gist of the present invention for solving the above problems is to detect the SOx concentration and / or the CO concentration of exhaust gas in a hopper of an electrostatic precipitator provided in a flue of a combustion furnace. The dust condition monitoring apparatus in the electrostatic precipitator hopper is provided with one or a plurality of SOx meters and / or CO meters and a recording apparatus for recording the change in the detected value with time.

Further, the temperature in the dust layer accumulated in the hopper of the electrostatic precipitator provided in the flue of the combustion furnace is detected 1
Alternatively, a dust condition monitoring device in the electrostatic precipitator hopper, which is provided with a plurality of temperature detectors and a recording device for recording a change with time of the detected value, is also a gist.

An SOx meter for detecting the SOx concentration of the exhaust gas in the hopper of the electrostatic precipitator provided in the flue of the combustion furnace, a CO meter for detecting the CO concentration of the exhaust gas, and the temperature in the dust layer. One or a plurality of at least one type of temperature detectors, and a threshold value for the pattern recognition that is preset by pattern-recognizing at least one temporal change of the SOx concentration, the CO concentration, and the temperature. The dust condition monitoring device in the electrostatic precipitator hopper equipped with a data processing device to be compared with

An exhaust gas derivation device that selectively guides a part of the exhaust gas in the plurality of hoppers of the electrostatic precipitator provided in the flue of the combustion furnace, and the SOx of the exhaust gas that is guided by the device. A dust state monitoring device in an electric dust collector hopper provided with a SOx meter and / or a CO meter for detecting the concentration and / or the CO concentration is also a gist.

The combustion furnace has a high-pressure blower, and the combustion furnace is stopped based on the stoppage of the blower. After the start-up fuel is burned to start the combustion furnace, the combustion is switched to the main fuel-fired combustion. In the case of a furnace, the concentration and / or the temperature and / or the comparison is started by the stop of the ventilator and ended by the switching. And

[0027]

In general, it is known that combustibles (especially coal and solid carbides) are oxidized at a low temperature in an oxygen atmosphere, and the temperature of the combustibles themselves rises to accelerate the oxidation rate and finally reach the ignition temperature. ing. In the process of this ignition, heavy oil ash becomes 200 to 250 ° C or higher and C
It has been confirmed that O is generated, and further, sulfur oxide SOx and a small amount of nitrogen oxide NOx are generated after ignition at about 400 ° C. or higher. Note that FIG. 11 is a diagram showing the CO generation amount of heavy oil ash in relation to temperature. From the figure, it can be seen that when the temperature in the dust layer in the hopper rises, the combustible carbon in the dust is actively thermally decomposed to generate CO.

Therefore, by recording the time-dependent change of the SOx concentration or NOx concentration of the atmosphere in the hopper or the temperature of the accumulated dust with the SOx meter, the CO meter or the thermometer, the pre-ignition combustion of the dust in the hopper is made at the initial stage. It is possible to easily find out by, and by taking measures such as dust extraction and cooling at an early stage, it is possible to prevent accidents such as breakdown of the ash processing device. When multiple SOx meters, CO meters, or thermometers are provided, SOx should be installed in each part of the hopper.
By providing a meter, a CO meter, or a thermometer, it is possible to monitor even the SOx and CO concentration distribution and temperature distribution in the hopper, and more precise monitoring becomes possible.

In the case of the dust condition monitoring device in the electrostatic precipitator hopper equipped with the data processing device, the threshold for pattern recognition is set in advance to a value considered to be dangerous if the dust temperature or the like further increases, If you recognize the change over time such as dust temperature and compare it with a preset threshold for pattern recognition, you can notify the worker by well-known means such as issuing an alarm when this threshold is exceeded. By doing so, it is possible to easily know that the inside of the hopper is in a dangerous state.

In the case of the dust condition monitoring device in the electrostatic precipitator hopper having the exhaust gas discharge device, a part of the exhaust gas in the plural hoppers of the electrostatic precipitator is selectively guided from the plural hoppers. SOx of this exhaust gas
If the concentration of CO or CO is detected, the concentration of SOx or CO in the exhaust gas of each hopper can be detected one after another even if the number of hoppers is large, and an SOx meter or CO meter is provided for each hopper. Economical with no need.

A combustion furnace in which the combustion furnace has a high-pressure blower, and the combustion furnace is stopped based on the stop of the blower, and the starting fuel is burned to start the combustion furnace, and then the combustion furnace is switched to the main fuel burning. In the dust condition monitoring device in the electrostatic precipitator hopper, the comparison with the concentration of SOx or CO, the dust temperature, or the threshold value is started by stopping the air blower and ended by the switching. In other words, it is economical because the dust is monitored only during the period from the stop of operation to the start of operation, which is a period during which the combustion furnace in which there is a danger of in-place combustion of dust in the hopper is not in operation.

[0032]

EXAMPLES Examples of the present invention will be described below. Figure 1
FIG. 3 is a diagram illustrating a schematic structure of a heavy-duty thermal power plant to which the dust state monitoring device in the electrostatic precipitator hopper according to the embodiment of the present invention is applied. Referring to the figure, this heavy-duty thermal power plant is equipped with a boiler 1, and heavy oil and air 4 are supplied into the boiler 1 and burned. 2 is an air preheater, 3
Is air supplied from a not-shown strong pressure fan (combustion air fan). EP5 has a plurality of hoppers 19 at the bottom thereof.
Is equipped with. The exhaust gas generated in the boiler 1 is dust-collected in EP5, and the exhaust gas after dust collection is discharged to the outside air by the chimney 8. The heavy oil supplementary dust 6 accumulated in the hopper 19 by the dust collection is intermittently sent to the exhaust gas treatment device (not shown) as shown in FIG. 5, for example, by opening the rotary seal 7. The heavy-duty thermal power plant to which the present embodiment is applied stops the operation by using a stop of a high-pressure blower (not shown) as a kick of a stop signal of the boiler 1. Further, in order to start the operation, the combustion is performed by burning the starting fuel (for example, light oil or heavy oil) and then switching to the main fuel (for example, fuel oil or coal), and the switching operation completes the starting operation.

Next, the structure of the dust condition monitoring device in the electrostatic precipitator hopper applied to such a heavy-duty thermal power plant will be described. The monitoring device comprises a sampling probe 10 provided above the heavy oil collecting dust 6 accumulated in the hopper 19. The sampling probe 10 is
A part of the exhaust gas in EP5 is taken out. A plurality of the sampling probes 10 are dispersed and arranged for each hopper 19. Each sampling probe 10 is connected to a gas suction pipe 11 through which the exhaust gas taken out by the sampling probe 10 flows, and a blower 12 is connected to the pipe 11.
Is provided. A filter 18 is provided downstream of the blower 12 of the gas suction pipe 11, and CO and SOx are provided further upstream thereof.
An analyzer 13 is provided. A plurality of gas switching valves 9 are provided on the upstream side of the blower 12 of the gas suction pipe 11 so as to correspond to each sampling probe 10. The plurality of gas switching valves 9 can be selectively opened and closed,
It is possible to switch electrically continuously.

Further, in the 6 layers of the heavy oil collecting dust of the hopper 19, a plurality of temperature detectors 1 are dispersed for each hopper 19.
4 are supported and provided.

The CO and SOx analyzer 13 detects the CO concentration and SOx concentration in the exhaust gas in EP5, and the temperature detector 14 detects the dust temperature. These detection signals are sent to the data recording device 15, The device 15 records the change with time of each detected value. The change over time of each detected value is displayed on the CRT16,
It is displayed for each hopper 19, each analyzer 13, and each detector 14. Further, the device 15 recognizes the change with time for pattern recognition, compares it with a preset threshold value for pattern recognition, and issues ANN, for example, when the value reaches or exceeds this threshold value. The threshold value can be variously set to a value that is considered dangerous if the temperature of the heavy oil-collected dust 6 and the like further increases.

Further, the dust condition monitoring device in the electrostatic precipitator hopper of this embodiment is turned on by the stop signal of the strong pressure fan (not shown), and the above-mentioned detection of the analyzers 13 and detectors 14 and the data recording device. The above-mentioned data processing of 15 is started, and it is turned off by the switching signal from the starting fuel burning to the main fuel burning, and the above-mentioned detection of each analyzer 13 and detector 14 and the above-mentioned data processing of the data recording device 15 are performed. And so on. After being turned off, the sample probe 10 and the gas suction pipe 11 are air-purged to prevent clogging of the pipe.

Next, the operation of this embodiment will be described. When the heavy-duty thermal power plant enters a stop operation, heavy oil-collecting dust 6 is accumulated in the hopper 19. Boiler 1
Each burner (not shown) in the figure is sequentially digested, the O ₂ concentration in the exhaust gas is also increased, and the temperature inside the boiler 1 is lowered. As shown in FIG. 9, THC (total hydrocarbons) also carries over to some extent in association with the burner extinguishing operation and purging operation (not shown).

The strong pressure blower (not shown) is stopped, which stops the operation of the heavy-duty thermal power plant as described above.
After that, the dust condition monitoring device in the electrostatic precipitator hopper of the present embodiment is turned on by the stop signal of the high pressure blower, and the monitoring of the heavy oil collecting dust 6 in the hopper 19 is started. The gas switching valve 9 is electrically and continuously switched, and the exhaust gas sucked by each sampling probe 10 is successively CO, SOx.
It is introduced into the analyzer 13 to detect CO concentration and SOx concentration. That is, the exhaust gas is taken in from the sampling probe 10 by suction of the blower 12, filtered by the filter 18, and then analyzed by the CO and SOx analyzer 13. In this way, each sampling probe 10
Then, the CO concentration and the SOx concentration of the exhaust gas taken in one after another are detected, and the detected values are recorded in the data recording device 15. The continuous detection of the exhaust gas taken in by each sampling probe 10 by such continuous switching by the gas switching valve 9 is repeated at a fixed time interval, and the change with time of the detection value for each hopper 19 and each sampling probe 10 is: It is recorded in the data recording device 15. Further, each temperature detector 14 detects the temperature of the heavy oil-collected dust 6 in the hopper 19, and the detected values are also recorded in the data recording device 15 for each hopper 19 and for each temperature detected value. .

The change with time of each detected value as described above is the CRT.
16 is displayed for each hopper 19, each analyzer 13, and each detector 14. Further, the data recording device 15 recognizes the change with time and compares it with a preset threshold value for pattern recognition, and when it reaches a value equal to or higher than this threshold value, for example, issues ANN. As a specific example of pattern recognition, FIG.
Is shown in. FIG. 2 shows a pattern recognition of the change in the CO concentration of the exhaust gas over time. For example, in the case of and, it is judged to be normal, and in the case of To issue.

Generally, combustibles (especially coal and solid carbides) are oxidized at a low temperature in an oxygen atmosphere, and the temperature of the combustibles themselves is increased to accelerate the oxidation rate.
It is known that the ignition temperature is finally reached. During the process of ignition, CO is generated in heavy oil ash at a temperature of 200 to 250 ° C or higher, and further, sulfur oxide SOx and a trace amount of nitrogen oxide NOx are generated after ignition at approximately 400 ° C or higher. Has been confirmed.

Therefore, according to the dust condition monitoring apparatus in the electrostatic precipitator hopper of this embodiment, the CO and SOx analyzer 13 is used.
Alternatively, the temperature detector 14 records the SOx concentration or NOx concentration of the atmosphere in the hopper 19 or the time-dependent change of the temperature of the accumulated heavy oil-collected dust 6 in the hopper 19. It is possible to easily find out at such a stage, and by taking measures such as withdrawing and cooling the heavy oil collecting dust 6 at an early stage, it is possible to prevent an accident such as a failure of an ash processing device (not shown). Also, C
Since a plurality of O, SOx analyzers 13 or temperature detectors 14 are provided, by providing CO, SOx analyzers 13 or temperature detectors 14 in each part of the hopper 19, the SOx and CO concentration distributions in the hopper and You can monitor even temperature distribution,
More precise monitoring becomes possible.

Further, the data processor 15 presets a threshold for pattern recognition to a value which is considered dangerous if the temperature of the heavy oil-collected dust 6 further rises, so that the temperature of the heavy-oil-collected dust 6 or the like changes with time. By recognizing the pattern and comparing it with a preset threshold value for this pattern recognition, the worker is informed that the ANN is emitted when the threshold value is exceeded and the inside of the hopper 19 is put into a dangerous state. You can easily know that there is.

Moreover, the gas switching valve 9 makes it possible to selectively guide a part of the exhaust gas from the plurality of hoppers 19 one after another. If the concentrations of SOx and CO in the guided exhaust gas are detected, Even if the number of hoppers 19 is large, the concentration of SOx and CO in the exhaust gas of each hopper 19 can be detected one after another, and it is not necessary to provide a CO and SOx analyzer 13 for each hopper 19, which is economical. .

Further, in the heavy-duty thermal power plant to which the dust condition monitoring device in the electrostatic precipitator hopper of the present embodiment is applied, the operation is stopped by using the stop signal of the high-pressure fan as the kick of the stop signal of the boiler 1. It is something to do. Further, in order to start the operation, the combustion is performed by switching the fuel to the main fuel after the fuel is started, and the startup operation is completed by this switching. For such a combustion furnace, as in the present embodiment, it is turned on by a stop signal of a strong pressure blower (not shown), and the above-mentioned detection of each analyzer 13 and detector 14 and the above-mentioned data of the data recording device 15 are performed. Processing is started, and again
If it is turned off by the switching signal from the starting fuel burning to the main fuel burning, and the above-mentioned detection of each analyzer 13 and the detector 14 and the above-mentioned data processing of the data recording device 15 are completed, strong pressure ventilation not shown It starts when the machine is stopped and ends when the machine is switched. That is, the heavy oil-collected dust 6 is monitored only during the period from the stop of operation to the start of operation, which is a period in which the heavy-duty thermal power plant is not in operation, where there is a danger of placing and burning the heavy oil-collected dust 6 in the hopper. It is economical.

Since the height of the layer of the heavy oil-collected dust 6 in the hopper 19 changes depending on the load and the dust processing time before the operation of the heavy-duty thermal power plant is stopped, only the temperature of the heavy-oil collected dust 6 is increased. It may be difficult to judge the possibility of in-place combustion of the heavy oil-collected dust 6. Therefore, it is also possible to judge only by the CO concentration, for example, the stack effect when the heavy-duty thermal power plant is out of operation. Since the CO concentration changes due to the flow of the exhaust gas due to the above, it is desirable to make a comprehensive judgment of the temperature of the heavy oil collected dust 6, the CO concentration, and the like, as in the present embodiment.

[0046]

As described above, according to the dust condition monitoring apparatus in the electrostatic precipitator hopper of the present invention described above, it is possible to easily find the in-fire combustion of the dust in the hopper at the initial stage, as described above. Accidents such as breakdown of the ash processing device can be prevented in advance.

Further, when a plurality of SOx meters, CO meters or thermometers are provided, more detailed monitoring becomes possible as described above.

Further, in the case of the dust condition monitoring device in the electrostatic precipitator hopper provided with the data processing device, it is possible to easily know that the hopper is in a dangerous state as described above.

Furthermore, in the case of the dust condition monitoring device in the above-mentioned electric dust collector hopper equipped with the exhaust gas discharge device, or when the combustion furnace has a high-pressure fan, the combustion furnace is stopped based on the stop of the fan. For the dust condition monitoring device in the electrostatic precipitator hopper, which is a combustion furnace that performs combustion by switching to main fuel combustion after starting fuel combustion for starting the combustion furnace, is economical as described above. Is.

[Brief description of drawings]

FIG. 1 is a diagram illustrating a schematic structure of a heavy-duty thermal ash treatment apparatus to which a dust state monitoring device in an electrostatic precipitator hopper according to an embodiment of the present invention is applied.

FIG. 2 is a diagram showing an example of pattern recognition of a temporal change in exhaust gas CO concentration by a dust state monitoring device in an electrostatic precipitator hopper according to an embodiment of the present invention.

FIG. 3 is a diagram showing an example of a dust collecting facility of a conventional coal-fired power plant.

FIG. 4 is a diagram showing an example of a conventional coal-fired ash processing apparatus.

FIG. 5 is a diagram showing an example of a conventional heavy-duty thermal ash treatment apparatus.

FIG. 6 is a diagram showing an example of a structure of a conventional electrostatic precipitator.

FIG. 7 is a diagram showing an example of a structure of a conventional electrostatic precipitator.

FIG. 8 is a diagram showing an example of a structure of a conventional electrostatic precipitator.

FIG. 9 is a diagram showing analysis results of THC concentration in a flue when a conventional coal-fired power generation boiler is stopped.

FIG. 10 is a diagram showing analysis results of THC concentration in a flue when a conventional coal-fired power generation boiler is activated.

FIG. 11 is a diagram showing the CO generation amount of heavy oil ash in relation to temperature.

[Explanation of symbols]

 5 Electrostatic precipitator (EP) 6 Heavy oil collecting dust 9 Gas switching valve 10 Sampling probe 11 Gas suction pipe 13 CO, SOx analyzer 14 Temperature detector 15 Data recording device 16 CRT 19 Hopper

Claims (5)

[Claims] 1. One or more SOx meters and / or CO meters for detecting SOx concentration and / or CO concentration of exhaust gas in a hopper of an electrostatic precipitator provided in a flue of a combustion furnace, and the detection. A dust condition monitoring device in an electrostatic precipitator hopper, which is provided with a recording device for recording a change in value over time. 2. One or a plurality of temperature detectors for detecting a temperature in a dust layer accumulated in a hopper of an electrostatic precipitator provided in a flue of a combustion furnace, and recording a temporal change of the detected value. The dust condition monitoring device in the electrostatic precipitator hopper equipped with the recording device. 3. A SOx meter for detecting SOx concentration of exhaust gas in a hopper of an electrostatic precipitator provided in a flue of a combustion furnace, a CO meter for detecting CO concentration of the exhaust gas, and a temperature in the dust layer. One or a plurality of at least one kind of temperature detectors for detecting, and a pattern recognition on preset pattern recognition by recognizing a temporal change of at least one of the SOx concentration, the CO concentration and the temperature. Dust condition monitoring device in the electrostatic precipitator hopper equipped with a data processing device for comparing with the threshold value of. 4. An exhaust gas discharge device for selectively guiding a part of exhaust gas in a plurality of hoppers of an electrostatic precipitator provided in a flue of a combustion furnace, and an exhaust gas guided by the device. The dust condition monitoring device in the electrostatic precipitator hopper equipped with the SOx meter and / or the CO meter for detecting the SOx concentration and / or the CO concentration of. 5. The combustion furnace has a high-pressure blower, and the combustion furnace is stopped based on the stoppage of the blower, and after starting fuel for starting the combustion furnace, combustion is switched to main fuel burning. The electrostatic precipitator according to any one of claims 1 to 4, wherein the concentration and / or the temperature and / or the comparison is started by stopping the ventilator and ended by the switching in the case of a combustion furnace to be performed. Dust condition monitoring device in the vessel hopper.