JPH08110027A - Combustion control method of dust incinerator - Google Patents

Abstract

PURPOSE: To clean waste gas by restricting the production of dioxin by calculating waste gas CO concentration from CO concentration and CO2 concentration and opening and closing a damper in response to the calculated value. CONSTITUTION: CO concentration, O2 concentration, and NOX concentration in waste gas exhausted from a dust incinerator are detected, and a CO concentration reduced value is calculated from the CO concentration and the O2 concentration and a waste gas CO concentration reduced value is calculated from the NOX concentration and the O2 concentration. A controller 27 controls the amount of air by automatically opening and closing an overfire air damper 15 in response to the calculated waste gas CO concentration reduced value while enabling the overfire air damper 15 to be manually operated by actuating an interlock when the calculated waste gas NOX concentration reduced value exceeds a preset upper limit set value and bringing about the opening of the overfire air damper 15 to predetermined opening. Hereby, production of dioxin can be restricted and hence the waste gas can be cleaned.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of controlling combustion in a refuse incinerator, which suppresses harmful substances in exhaust gas generated by burning the municipal waste in the incinerator.

[0002]

2. Description of the Related Art In a conventional refuse incinerator, waste such as municipal waste supplied to a hopper chute is supplied onto a stoker (combustion grate) by a feeder provided below the hopper chute. Further, the main combustion air is sent to a compartment air box under the stoker by a blower and supplied to this stoker. The distribution of the main combustion air on the stoker is performed by adjusting the opening of the damper with a manual damper opening setting device. On the other hand, the overfire air is supplied to the lower part of the incinerator on the stoker by a blower. The distribution of the main combustion air amount and the overfire air amount is set by controlling the air amount of each blower while monitoring the combustion state. The high temperature combustion exhaust gas generated by the combustion on the stoker is guided to the boiler water tube panel part that constitutes the incinerator, and heat is exchanged there to generate steam.

Exhaust gas generated in incinerators such as municipal waste contains carbon dioxide, water vapor, nitrogen, oxygen, and harmful substances such as nitrogen oxides (NO _x ). In the above-mentioned conventional refuse incinerator, when the NO _X concentration exceeds the reference value, the combustion air flow rate is automatically reduced to suppress the combustion of the dust and suppress the generation of NO _X.

[0004]

In the above-mentioned conventional refuse incinerator, when the NO _X concentration exceeds the reference value, the combustion air flow rate is reduced to suppress the generation of NO _X. However, even if the combustion in the refuse incinerator is macroscopically stable, it remains microscopically unstable, and carbon monoxide and hydrocarbons are locally generated due to lack of oxygen. It is generated as unburned gas. In addition, dioxins and the like are generated from the chlorine content and organic substances in the waste, and may be discharged to the outside before complete thermal decomposition in the furnace. Although this dioxin is a trace contaminant, the installation of a device for suppressing this dioxin was insufficient.

The present invention solves such a problem, and provides a combustion control method for a refuse incinerator in which the generation of dioxins is suppressed by controlling the CO concentration to purify the exhaust gas. With the goal.

[0006]

In order to achieve the above object, the combustion control method for a refuse incinerator of the present invention is such that while waste is supplied from a hopper to the incinerator, air for main combustion and In a refuse incinerator in which overfire air is fed and burned, CO concentration, O ₂ concentration and NO _x concentration in exhaust gas discharged from the incinerator are detected, and exhaust gas CO concentration is detected from the CO concentration and the O ₂ concentration. while calculating a conversion value, the NO _X concentration and the O ₂ concentration calculated exhaust gas NO _X concentration corresponding values from the overfire air damper automatically opens and closes in response to the computed exhaust gas CO concentration conversion value to air While controlling the amount, the calculated exhaust gas N
When the O _X concentration conversion value exceeds a preset upper limit setting value, an interlock is activated to manually operate the overfire air damper and the opening degree of the overfire air damper is set to a predetermined opening degree. It is characterized by.

[0007]

The concentration of dioxin generated from the refuse incinerator has a correlation with the CO concentration, and if the generation of this CO is suppressed, the generation of dioxin can also be suppressed. On the other hand, combustion air is divided into main combustion air and overfire air, of which overfire air is effective for complete combustion and thermal decomposition of unburned gas and harmful gas components generated by local incomplete combustion. In addition, it also contributes to uniform heat load in the incinerator. Therefore, CO in exhaust gas
The exhaust gas CO concentration conversion value is calculated from the concentration and the O ₂ concentration,
When the exhaust gas CO concentration conversion value rises, the damper is opened to increase the air amount to promote combustion and reduce CO. On the other hand, when the exhaust gas CO concentration conversion value decreases, the damper is closed to reduce the air amount. NO _x decreases. Further, the exhaust gas NO from NO _X concentration and the O ₂ concentration in the exhaust gas
_{An X} concentration conversion value is calculated, and when this exhaust gas NO _X concentration conversion value exceeds the upper limit set value, the interlock operates and the damper can be manually operated, and the damper opening is returned to a predetermined opening to reduce NO _X. Suppresses the increase in the concentration of.

[0008]

Embodiments of the present invention will now be described in detail with reference to the drawings.

FIG. 1 is a schematic configuration showing a combustion control device of a refuse incinerator for carrying out a combustion control method of the refuse incinerator according to an embodiment of the present invention, FIG. 2 is a control block of the combustion control device, and FIG. FIG. 4 shows a flow chart of combustion control, and FIG. 4 shows a graph showing the judgment standard of the CO concentration conversion value.

In the waste incinerator combustion control system of this embodiment, as shown in FIG. 1, the waste such as municipal waste supplied to the hopper chute 11 is stokered by a feeder 12 provided below the hopper chute 11. Combustion grate)
13 is supplied. The main combustion air is supplied to the stoker 13 by a blower (not shown). On the other hand, the overfire air is supplied to the lower part of the incinerator 14 on the stoker 13 by a blower (not shown). The distribution of this overfire air amount is controlled by the opening / closing operation of the overfire air damper 15. The high-temperature combustion exhaust gas generated by the combustion on the stoker 13 is guided to the boiler 16 adjacent to the incinerator 14, and is sent to the bag filter 18 via the exhaust gas passage 17. Here, the exhaust gas has its dust and the like removed by the bag filter 18, is denitrated by the catalytic denitration device 19, and is then released into the atmosphere through the chimney 21 by the induced draft fan 20.

An O ₂ concentration detector 22 and a CO concentration detector 23 are provided between the bag filter 18 and the catalytic denitration device 19 in the exhaust gas passage 17 of the combustion control device for such a refuse incinerator. , O ₂ concentration detector 22 detects the O ₂ concentration in the exhaust gas, the CO concentration detector 23 is adapted to detect the CO concentration in the exhaust gas. Further, the exhaust gas channel 17 is NO _X concentration detector 24 is provided located between the induced draft fan 20 and stack 21, this NO
_{The X} concentration detector 24 is adapted to detect the NO _X concentration in the exhaust gas before being released into the atmosphere.

[0012] CO concentration calculator 25, and CO concentration in the exhaust gas detected by the O ₂ concentration detector in the exhaust gas detected by the 22 O ₂ concentration and the CO concentration detector 23 is input as data, the The CO concentration calculator 25 calculates an exhaust gas CO concentration conversion value (O ₂ 12% conversion value) from the input CO concentration and O ₂ concentration. Further, the NO _X concentration calculator 26, and the concentration of NO _X in the detected exhaust gas by the O ₂ concentration detector in the exhaust gas detected by the 22 O ₂ concentration and the NO _X concentration detector 24 is inputted as data The NO _x concentration calculator 26 calculates the exhaust gas NO _x concentration conversion value (O ₂ 12% from the input NO _x concentration and O ₂ concentration).
Calculate the converted value). Then, the CO concentration calculator 25 and the NO _X concentration calculator 26 output the calculated exhaust gas CO concentration conversion value and exhaust gas NO _X concentration conversion value to the control device 27.

The control device 27, as shown in FIG.
A CO concentration comparison unit 28 and a NO _X concentration comparison unit 29,
The CO concentration comparison unit 28 controls the overfire air damper opening / closing device 30 according to the exhaust gas CO concentration conversion value, and automatically opens / closes the overfire air damper 15 to control the amount of overfire air. That is, this CO concentration comparison unit 2
8, the CO concentration upper limit value and the CO concentration lower limit value are set in advance, the exhaust gas CO concentration conversion value and the CO concentration upper limit value are compared, and when the exhaust gas CO concentration conversion value exceeds the CO concentration upper limit value, it is over. Fire air damper opening / closing device 30
Thus, the overfire air damper 15 is opened to increase the amount of overfire air. On the other hand, exhaust gas CO
When the concentration conversion value does not exceed the CO concentration upper limit value, the exhaust gas CO concentration conversion value is compared with the CO concentration lower limit value,
When the exhaust gas CO concentration converted value is lower than the CO concentration lower limit value, the overfire air damper opening / closing device 30 closes (squeezes) the overfire air damper 15 to reduce the amount of overfire air.

Further, the NO _X concentration comparison unit 29 is configured to detect the exhaust gas N
When the O _X concentration conversion value exceeds a preset NO _X concentration upper limit set value, the interlock actuating device 31 is operated, the overfire air damper 15 can be manually operated, and the opening degree of the overfire air damper 15 is increased. To a predetermined opening. That is, even when the control device 27 becomes abnormal due to the interlock operation device 31 and the CO concentration control cannot be performed, the overfire air damper 15 can be manually opened and closed.

Here, the combustion control method of the refuse incinerator of this embodiment will be described based on the flow chart of the combustion control shown in FIG.

As shown in FIG. 3, in step S1, the CO concentration detector 23 detects the CO concentration in the exhaust gas flowing in the exhaust gas passage 17, and outputs the detection signal to the CO concentration calculator 25. Further, in step S2, the O ₂ concentration detector 22 detects the O ₂ concentration in the exhaust gas, and outputs the detection signal to the CO concentration calculator 25 and the NO _x concentration calculator 26. Further, in step S3, the NO _X concentration detector 2
4 detects the concentration of NO _X in the exhaust gas prior to atmospheric discharge, and outputs the detection signal to the NO _X concentration calculator 26.

Then, in step S4, the CO concentration calculator 25 calculates the exhaust gas CO concentration conversion value U (O ₂ 12% conversion value) from the input CO concentration and O ₂ concentration, and the calculated exhaust gas CO concentration conversion value. The value is output to the controller 27. In step 5, NO _X concentration calculator 26 calculates an exhaust gas NO _X concentration corresponding value V from NO _X concentration and the O ₂ concentration inputted (O ₂ 12% conversion value), the exhaust gas NO _X concentration conversion value Is output to the control device 27.

In step S6, the N of the controller 27 is
O_XThe concentration comparison unit 29 determines that the exhaust gas NO _XConcentration conversion value V and N
O_XExhaust gas NO_XConcentration conversion
Value V is NO_XIf it is smaller than the density upper limit set value A,
If it is larger, move to step S9.
To go. Then, in step S9, the interlock work
The interlock actuator 31 is activated by outputting a motion signal.
And the overfire air damper 15 can be operated manually.
Open this overfire air damper 15
Degree to the specified opening. Therefore, this interlock operation
The device 31 presets the amount of overfire air.
Return to the value that was set, NO_XThe increase in concentration is suppressed. Also,
An abnormality occurs in the control device 27 and the CO concentration cannot be controlled.
The overfire air damper 15 manually
You can open and close with. In addition, this interro
The lock fire device 31 when operating
Since it is necessary to adjust the opening of the damper 15, set it in advance.
Also, it is designed to return to a predetermined opening.

In step S7, the controller 2
The CO concentration comparing unit 28 of No. 7 compares the exhaust gas CO concentration conversion value U with the CO concentration upper limit value H, and the CO concentration conversion value U is CO
If it is smaller than the density upper limit value H, the process proceeds to step S8, while if it is larger, the process proceeds to step S10. Then, in step S10, an overfire air damper open signal is output to output the overfire air damper opening / closing device 3
When 0, the overfire air damper 15 is opened to increase the amount of overfire air. As described above, when the exhaust gas CO concentration conversion value U exceeds the CO concentration upper limit value H, the combustion in the incinerator 14 is promoted by opening the overfire air damper 15 to increase the air amount, and C
O decreases.

On the other hand, in step S8, the CO concentration comparison unit 28 compares the exhaust gas CO concentration converted value U with the CO concentration lower limit value L, and the exhaust gas CO concentration converted value U is the CO concentration lower limit value L.
If it is larger, the process returns to step S1 and the above-described control is repeated. If the exhaust gas CO concentration conversion value U is smaller than the CO concentration lower limit value L, the process proceeds to step S11 to output a closing (throttle) signal of the overfire air damper, and the overfire air damper opening / closing device 30 causes the overfire air damper to open. 15 is closed (squeezed) to reduce the amount of overfire air. As described above, when the exhaust gas CO concentration conversion value U is lower than the CO concentration lower limit value L, the air amount is excessive, so the air amount is reduced by reducing the opening degree of the overfire air damper 15, and NO _X is reduced.

The change in the exhaust gas CO concentration conversion value U in the exhaust gas flowing through the exhaust gas passage 17 is shown in the graph of FIG. That is, the combustion in the refuse incinerator remains small and unstable, and unburned gas is generated due to local excess or deficiency of oxygen, and the CO concentration in the exhaust gas (exhaust gas CO concentration from organic matter in the waste is generated. The converted value U) rises, dioxin and the like are produced, and the NO _x concentration rises. Therefore, the CO concentration upper limit value H and the CO concentration lower limit value L are set, and when the exhaust gas CO concentration converted value U deviates from this range, the overfire air damper 15 is set.
The opening of is being adjusted.

[0022]

As described above in detail with reference to the embodiments, according to the combustion control method of the refuse incinerator of the present invention, the CO concentration and the O ₂ concentration in the exhaust gas discharged from the incinerator are used to detect the exhaust gas CO. Concentration conversion value is calculated and NO in exhaust gas
_An exhaust gas NO _x concentration conversion value is calculated from the _X concentration and O ₂ concentration, and a damper of overfire air is automatically opened and closed according to the exhaust gas CO concentration conversion value to control the air amount,
When the exhaust gas NO _x concentration conversion value exceeds a preset upper limit setting value, the interlock is activated to manually operate the overfire air damper, and the opening degree of the overfire air damper is set to a predetermined opening degree. Therefore, for example, when the exhaust gas CO concentration conversion value rises, the combustion in the incinerator is promoted by opening the overfire air damper and increasing the air amount, and it is possible to reduce CO and suppress the generation of dioxins. , it is possible to reduce the opening of the overfire air damper when the exhaust gas CO concentration conversion value is lowered to reduce the NO _X by reducing the amount of air. Further, when the exhaust gas NO _x concentration conversion value exceeds a preset upper limit set value, the interlock is operated to set the opening of the overfire air to a predetermined opening, thereby suppressing the increase of the NO _x concentration. be able to. As a result, the exhaust gas generated in the refuse incinerator can be cleaned.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a combustion control device of a refuse incinerator for implementing a combustion control method of the refuse incinerator according to an embodiment of the present invention.

FIG. 2 is a control block diagram of a combustion control device.

FIG. 3 is a flowchart of combustion control.

FIG. 4 is a graph showing a criterion for determining a CO concentration conversion value.

[Explanation of symbols]

11 Hopper Chute 13 Stoker 14 Incinerator 15 Overfire Air Damper 17 Exhaust Gas Channel 22 O ₂ Concentration Detector 23 CO Concentration Detector 24 NO _X Concentration Detector 25 CO Concentration Calculator 26 NO _X Concentration Calculator 27 Control Unit U Exhaust CO Concentration conversion value V Exhaust gas NO _X concentration conversion value A NO _X concentration upper limit setting value H CO concentration upper limit value L CO concentration lower limit value

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Shigeo Sasaki 12 Nishiki-cho, Naka-ku, Yokohama-shi, Kanagawa Mitsubishi Heavy Industries, Ltd. Yokohama Works

Claims (1)

[Claims] 1. In a waste incinerator in which waste is supplied from a hopper to the incinerator, while main combustion air and overfire air are sent to the incinerator to burn the waste gas, the exhaust gas discharged from the incinerator CO concentration and O ₂ concentration, NO
_{The X} concentration is detected, and the exhaust gas C is detected from the CO concentration and the O ₂ concentration.
An O concentration conversion value is calculated, and the NO _X concentration and O
_{2 The} exhaust gas NO _x concentration conversion value is calculated from the concentration, and the damper of the overfire air is automatically opened and closed according to the calculated exhaust gas CO concentration conversion value to control the air amount, while the calculated exhaust gas NO _x When the concentration conversion value exceeds a preset upper limit set value, an interlock is activated to manually operate the overfire air damper, and the opening degree of the overfire air damper is set to a predetermined opening degree. Combustion control method for waste incinerator.