JPH0966230A - Waste refuse measuring device and control of combustion using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect the wt. and vol. of the waste refuse charged in an incinerator within a real time by providing the measuring device with a flap damper consisting of a flap plate and the counter wt. taking the moment balance of the flap plate to the inlet of a waste refuse charging chute. SOLUTION: Urban waste refuse is transferred to a drum feeder 4 while roughly crushed by a transfer screw 3 to be diffused and, after a weighing flap damper 6 is operated, the urban waste refuse is allowed to fall on a charging chute 5 to be allowed to flow in a fluidized bed incinerator 12. Then, the waste refuse is allowed to fall on a fluidized bed formed from a fluidizing substance 10 to be heated, dried and incinerated. At this time, the opening signal of the weighing flap damper 6 is sent to a combustion control device 13 and the charging wt. of the waste refuse is determined on the basis of a weighing flap damper opening degree-waste refuse wt. characteristic curve. Actual fuel quantity is calculated from a waste refuse wt.-actual fuel characteristic curve on the basis of the waste refuse wt. and the quality of waste refuse and combustion air introducing quantity is controlled on the basis of the actual fuel quantity.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a garbage supply measuring device and a combustion control method using the same, and particularly to a real-time measurement of the weight and volume of the garbage thrown into a combustion furnace in a waste incinerator such as municipal refuse. By auto-detecting the amount of fuel to the incinerator by detecting it in advance, and by performing stricter combustion control, it is possible to prevent the generation of pollutants, and a waste supply measurement device and combustion control using this Regarding the method.

[0002]

2. Description of the Related Art Waste incineration facilities have a risk of generating pollutants such as exhaust gas, waste water, and bad odor during the incineration process, and comply with pollution control regulations such as the Air Pollution Control Law. Must. On the other hand, unlike in fossil fuels such as heavy oil and coal, the incinerated waste has a low calorific value that varies depending on the season, weather, collection area, etc., and has a large water content, and its shape, size and density are diverse. Therefore, it has a characteristic that the burning rate is not uniform. Therefore,
In a waste incinerator that incinerates such waste, the combustion state is constantly monitored, and nitrogen oxide (NOx), carbon monoxide (C
It is necessary to suppress the generation of environmental pollutants such as O).

A fluidized bed type incinerator, which is one of the refuse incineration methods used in municipal waste incineration facilities, fills the bottom of the furnace with small-diameter sand as a fluidizing medium and introduces forced air for fluidization from the lower part of the sand. The layer is formed, and the waste is dried and incinerated in a high-temperature fluid medium, and the waste put in the incinerator is almost completely incinerated. Since the amount of dust input varies depending on the type and shape of dust, etc., the combustion state is controlled by detecting the oxygen amount in the furnace with an O ₂ sensor or detecting the flame in the furnace with a brightness sensor. Generation of CO and CO is suppressed.

In such a refuse incineration facility, the actual fuel amount supplied to the load setting is measured and the air amount distribution corresponding to it is performed, like the combustion control of a boiler that burns fossil fuel such as heavy oil or coal. Since it is not possible to perform strict combustion control by setting the value, the amount of waste input is set based on past experience based on predetermined load settings and waste quality (low heating value of waste and bulk specific gravity of waste) Based on the control of adjusting the amount of air to be used, the amount of air was finely adjusted from the O ₂ concentration and the in-furnace brightness in time.

16 and 17 are explanatory views showing a conventional dust supply device and a combustion control method thereof, respectively. In FIG. 16, a conventional refuse supply device includes a refuse input hopper 1 for receiving municipal waste 2, a transfer screw 3 provided at the bottom of the refuse input hopper 1, and a drum provided downstream of the transfer screw 3. A fluidized bed type incinerator 1 for the feeder 4 and the waste 2 diffused by the drum feeder 4
2, a charging air control damper 8 provided on a side wall of the fluidized bed incinerator 12, an O ₂ sensor 11 provided in an exhaust gas flue in a downstream of the fluidized bed incinerator 12, It mainly comprises a combustion control device 13 which controls the combustion air control damper 8 based on the output signal of the O ₂ sensor 11 to set the amount of combustion air flowing into the incinerator.

In such a structure, combustion control has been performed as follows. That is, in FIG. 17, first, while the operator sets the load in the combustion load input unit 14 of the combustion control device 13, the waste quality is checked and the waste quality input unit 15 is used to set, for example, low quality waste, standard waste, and high quality waste. Set garbage quality such as. Next, the heat input amount calculation unit 16 calculates the heat input amount from the set load and dust quality, and controls the combustion air amount according to the calculated heat input amount. Cascade first stage O
_{The 2} control unit 17 calculates the excess O ₂ corresponding to the heat input amount, and the combustion air volume is set by the deviation between this value and the O ₂ sensor output 19. The combustion air amount control unit 18 compares the air amount set by the O ₂ control unit 17 in the preceding stage with the combustion air flow rate sensor output 20, and the combustion air control damper 8
Instruct to increase or decrease the air volume. As described above, in the conventional technique, the heat input amount is set independently of the actual input dust amount and heat amount, and it is adjusted by O ₂ control. As for the O ₂ value, the dust burns in the furnace, the gas passes through the duct, and the O ₂
Since it is obtained after the measurement delay of the sensor, there is a large time delay from the dumping of dust to the start of control.
There was a problem of causing the generation of CO and CO.

That is, in the conventional combustion control method for a refuse incinerator, after detecting the combustion result of the refuse in the incinerator,
Since it is a follow-up control that adjusts the amount of combustion air, there is a problem in that there is a large time delay and it is not possible to follow a sudden change in the amount of input dust, and when the amount of input dust is suddenly increased, the amount of NOx generated Tended to grow. On the other hand, there is a problem that the gas temperature in the furnace decreases and CO is generated if the so-called dust-out condition continues due to emptying of the dust hopper or entanglement of dust in the dust supply device. The CO concentration is almost 0 ppm during normal combustion, but it may be 1000 ppm or more when the temperature inside the furnace is reduced due to the continuous exhaustion of dust. C generated
O is usually evaluated as an average value for 4 hours, but when the amount of garbage input is not constant and the so-called waste state continues for several minutes, it becomes 4
Since the time average value greatly increases, the detection of burnout and combustion control are particularly important technologies in waste incineration.

[0008] On the other hand, a method has been proposed in which dust before being put into a furnace is detected by a sensor using a microwave or image processing by an ITV camera and the combustion air amount is controlled in advance. It is difficult for the sensor to detect dust accurately because the applied microwaves are diffusely reflected. On the other hand, the image processing using the ITV camera has a problem that it is difficult to extract the contour of the dust because the dust on the wall surface of the furnace, which is the background portion, is contaminated. In addition, there is a problem that dust adheres to the sensor unit and the camera unit, which makes it more difficult to measure the actual fuel amount of dust before incineration and to control combustion air in advance.

[0009]

As described above, the conventional O
₂ Control and combustion control by the in-furnace combustion sensor have the problem that they cannot follow sudden changes in the waste supply amount because they are follow-up controls that capture the state quantity after combustion. In addition, the sensor part of an optical dust detector such as an ITV camera is contaminated with dust in a short time, so cleaning work is required, and there is a problem that continuous operation cannot be performed for a long time. There was a problem such as irregular reflection of microwaves depending on the quality, and the accuracy was poor. Therefore, combustion control using these is not accurate.

An object of the present invention is to solve the above-mentioned problems of the prior art and to detect a dust input amount as a highly reliable preceding value, and a dust supply measuring device using the same.
It is an object of the present invention to provide a combustion control method capable of effectively suppressing the generation of pollutants.

[0011]

[Means for Solving the Problems] The above-mentioned object is to install a measuring flap damper and / or a flap drop detecting flap damper at the outlet of a dust supply device or a throw-in chute, and use the measuring flap damper to determine the state of waste and the weight of thrown dust. By detecting that a large amount of dust has been input within a short time by the flap detection flap damper, and controlling the amount of combustion air introduced into the incinerator based on these detected values. Can be achieved.

That is, the invention claimed in the present application in order to achieve the above object is as follows. (1) In a waste supply device in which waste received by a hopper is transferred by a screw and introduced into an incinerator through a charging chute, a flap-shaped member arranged at the entrance of the charging chute to receive the waste transferred by the screw. And a flap-shaped plate and a counterweight for balancing moments are provided, and a rotation angle transmitter is provided on a rotation shaft of the measurement flap damper. (2) The counterweight of the weighing flap damper is made heavier by a predetermined weight than the flap-shaped plate, and the flap-shaped plate is opened when dust having a certain weight or more is accumulated on the flap damper. (1) The garbage supply measuring device according to the description. (3) The refuse supply measuring device according to (1), wherein the flap-shaped plate is divided into a plurality of strips, and each strip-shaped flap plate is provided with a rotation angle transmitter. (4) Do not touch the dust when the dust below the rated amount passes through the charging chute in the downstream of the measuring flap damper,
Alternatively, the present invention is characterized by the provision of a fall-off detection device having a flap-shaped plate arranged with a predetermined clearance with respect to the inner wall surface of the charging chute so as to show a relatively small opening degree even if touched. The waste supply measuring device according to any one of (1) to (3).

(5) A combustion control method using the dust supply device according to any one of (1) to (4), wherein the opening of the measurement flap damper is detected, and the detected value and the value are obtained in advance. Using a waste supply measuring device characterized in that the weight of refuse input is determined from the relationship between the measurement flap damper opening and the weight of waste, and the amount of combustion air introduced into the incinerator is controlled based on the weight input. The combustion control method used. (6) The product of the amount of dust input based on the opening of the measurement flap damper and the preset amount of heat generated by the dust per unit weight is regarded as the measured value of the input fuel amount, and based on the input fuel amount. A combustion control method using the refuse supply measuring device according to (5), characterized in that the amount of combustion air introduced into the incinerator is controlled. (7) When the metering flap damper does not operate for a predetermined opening or more for a predetermined time or more, it is determined that dust has run out, and based on this, the amount of combustion air introduced is reduced (5) or ( 6) A combustion control method using the waste supply measuring device described in the above. (8) A combustion control method using the dust supply measuring device according to (4), wherein when the dust drop detector detects that a large amount of dust is supplied within a short time, the incinerator is inspected. A combustion control method using a refuse supply measuring device, characterized in that the amount of introduced combustion air is temporarily increased.

According to the present invention, in a fluidized bed-type refuse incinerator, a flap damper is installed at a position where the refuse flow path is blocked at the outlet of the refuse supply device or a charging chute, and this is used as a weighing flap damper. A flap damper, which has a predetermined clearance with respect to the dust flow path of the chute and is activated by passage of dust having a certain volume or more, is used as a flap drop detection flap damper.

The metering flap damper is stopped when there is no dust passing through the throw-in chute, and when this state continues for a predetermined time or longer, it is determined that the dust is out. The dust out condition causes the temperature of the air in the furnace to drop and incomplete combustion occurs.Therefore, when the dust out condition is detected by this flap damper, the combustion air control damper is promptly throttled to generate nitrogen oxides and CO. Is suppressed. In addition, the metering flap damper can measure the actual amount of waste fuel by obtaining the correlation between the weight of the passing dust and the opening of the flap damper in advance. For, the amount of combustion air introduced into the incinerator is automatically controlled based on the actual amount of waste fuel measured by the above method.

The looseness detection flap damper operates when dust having a certain volume or more passes through the throw-in chute, and determines that the looseness has occurred. A large amount of dust is thrown into the incinerator in a short time, so-called throat drop occurs because incomplete combustion occurs due to a temporary shortage of combustion air. When the occurrence of dropping is detected, the combustion air control damper is opened promptly, the amount of combustion air introduced into the incinerator is increased, and the generation of CO is suppressed.

[0017]

Next, the present invention will be described in more detail with reference to examples. FIG. 1 is an explanatory view showing an embodiment of the dust supply amount measuring device of the present invention. The difference between this device and the conventional device shown in FIG. 16 is that a metering flapper damper 6 is provided at the inlet of the charging chute 5 that guides the dust diffused by the drum feeder 4 to the fluidized bed incinerator 12, and the inside of the charging chute 5 is provided. A throat drop detection flap damper 7 is provided, and the detection signals of the measurement flapper damper 6 and the throat drop detection flap damper 7 are sent to the combustion control device 13, respectively, and the amount of combustion air introduced is controlled based on this. That is the point.

Municipal waste 2 thrown into the garbage throwing hopper 1
Is transferred to the drum feeder 4 while being roughly crushed by the transfer screw 3 and diffused, and the measurement flapper damper 6
After operating, the charging chute 5 drops and flows into the fluidized bed incinerator 12. At this time, the flutter drop detection flapper damper 7 also operates depending on the volume of dust. The municipal solid waste 2 that has flowed into the fluidized bed incinerator falls into a fluidized bed formed of a fluidized substance 10 that is fluidized by fluidized air introduced from an air diffuser 9, is heated and dried, and burns. It flows out from the upper part of the incinerator 12, flows through the flue, is treated, for example, with exhaust gas, and is then released into the atmosphere.

The combustion control method in this embodiment will be described in detail with reference to FIG. 2 showing the combustion control device 13. FIG.
, 6 is a measurement flap damper, 7 is a flap drop detection flap damper, 8 is a combustion air control damper,
15 is a refuse quality input unit, 16 is a heat input calculation unit, 17 is O ₂
A control unit, 18 is a combustion air amount control unit, 19 is an O ₂ sensor output, and 20 is a combustion air flow rate sensor output.

The opening signal of the measurement flap damper 6 is sent to the heat input amount calculation unit 16 of the combustion control device 13, and the dust input weight is determined on the basis of the measurement flap damper opening-dust weight characteristic curve obtained in advance. The actual fuel amount is calculated from the waste weight-actual fuel characteristic line based on this waste weight and the waste quality input by the operator to the waste quality input unit 15 at the start of work, for example, low quality waste, standard waste, and high quality waste. Then, the amount of combustion air introduced is controlled based on the actual fuel amount. The O ₂ controller 17 calculates excess O ₂ corresponding to the actual fuel amount, and the combustion air introduction amount is set by the deviation between this value and the sensor output 19. The combustion air flow rate control unit 18 compares the air flow rate set by the O ₂ control unit 17 in the preceding stage with the combustion air flow rate sensor 20, and instructs the combustion air control damper 8 to increase or decrease the air flow rate.

Next, the measuring flap damper and the drop flap damper of this embodiment will be described in detail. FIG. 3 is an enlarged view of the measuring flap damper applied to this embodiment, and FIG. 4 is a sectional view taken along the line IV-IV of FIG. In the figure, in the downstream of the drum feeder 4, at the inlet of the charging chute 5, a flap-shaped plate arranged to receive the dust diffused by the drum feeder 4 and a moment balance with the flap plate. A measuring flap damper having an attached counterweight (not shown) is provided, and a rotary encoder, for example, is provided as a rotation angle detector 21 on the rotation shaft of the measuring flap damper.

The measuring flap damper 6 is provided with a charging chute 5.
The opening angle of the flap damper is detected by the rotation angle detector 21 attached to the flap damper shaft. The detected angle is converted into an electric signal, and then the combustion angle is detected. It is transmitted to the combustion air amount control unit 18 of the control device 13. Next, the operation of the measuring flap damper will be described with reference to FIG. In the figure, 22 indicates a dust input area and 23 indicates a dust cut area. The combustion air amount control unit 18 of the combustion control device 13 constantly monitors the metering flap damper opening degree, determines that the dust-out region 23 is out of dust when the dust-out region 23 continues for a certain time or longer, and installs it in the incinerator 12, for example. By narrowing down the combustion air control damper 8 thus obtained, incomplete combustion due to low temperature and cooling of the gas temperature in the furnace are prevented.

FIG. 6 is an explanatory view showing the principle of measuring the actual fuel amount of dust by the measuring flap damper. In the figure, 2
Reference numeral 4 is a measurement flap damper opening-dust weight characteristic curve. The measuring flap damper has a unique momentum balance between the weight of the dust on the flap plate and the opening of the flap damper, which is based on the principle that the flap plate and the counterweight balance the moment. Since such a relationship is determined, the weight of refuse is measured using this relationship.

The product of the dust input amount obtained based on the opening of the flap damper and the heat generation amount per unit weight selected in advance is regarded as a measurement value of the input fuel amount, and the combustion air amount is based on this. Can be controlled. That is, reference numeral 25 in the figure indicates the garbage weight-actual fuel amount characteristic. The amount of dust as fuel has a strong tendency to depend on the weight rather than the volume, and there is a substantially proportional relationship between the dust weight and the actual fuel amount as shown by 25 in the figure. Therefore, the slope of the dust weight-actual fuel amount characteristic 25 is determined based on the result of the dust quality setting performed by the operator, and the actual fuel amount is measured from the dust weight. In this way, the automatic controllability of combustion is improved by measuring the actual fuel amount from the opening degree of the measurement flap damper and the dust quality set by the operator.

As described above, the metering flap damper in this embodiment is installed at the inlet of the charging chute, the rotary angle transmitter such as a rotary encoder is attached to the flap damper shaft, and the flap damper opening is converted into an electric signal for combustion. It is transmitted to the combustion air amount control unit 18 of the control device 13. In addition, the dust cut state can be detected by adjusting with a counterweight or the like so as to stop at the position where the closing chute is closed. Furthermore, the actual fuel amount can be measured based on the weight of the dust by previously storing the correlation between the weight of the dust passing through and the opening degree of the flap damper in the calculation unit.

FIG. 7 is an enlarged view of a flap drop detecting flap damper applied to this embodiment, and FIG. 8 is a view of VIII-VIII of FIG.
It is a line arrow direction cross section. In the figure, a throat drop detection flap damper 7 having a limit switch 26 such as a position sensor is provided on the upper inner wall surface in the middle of the charging chute 5, and the flap plate of the throat drop detection flap damper 7 is provided. A dead zone due to the clearance is provided between the inner wall surface of the chute 5 and the lower inner wall surface of the chute 5. Therefore, when the volume of the dust 2 passing through the charging chute 5 is equal to or larger than the clearance width between the flap plate and the lower inner wall surface of the charging chute, the opening degree corresponding to the dust volume is shown. The limit switch 26 detects when the flap damper opening exceeds a predetermined angle, and the detection signal is a combustion air amount control unit 18 of the combustion control device 13.
Is transmitted to

The operation of the flap detection flap damper is shown in FIG.
This will be described with reference to FIG. In the figure, 27 is a flap drop detection stop region, 28 is an operation region,
29 is a drop level, 30 is a limit switch OF
The F state, 31 indicates the ON state of the limit switch. The looseness detection flap damper stop region 27 indicates whether dust is normally thrown in or is out of dust within the clearance between the flap plate and the inner wall surface of the charging chute, and there is no looseness. On the other hand, in the throat drop detection flap damper operation region 28, dust having a volume larger than the clearance between the flap plate and the inner wall surface of the chute is thrown in, and it is confirmed that throat drop or a state close to throat drop occurs. Shows.

In this embodiment, the limit switch is set to the ON state at the flap damper opening at the time of throwing in the dust, which produces a large amount of nitrogen oxides. You can set level 29,
It becomes possible to catch the drop in the ON state of the limit switch shown by 31 in FIG. The combustion air amount control unit 18 of the combustion control device 13 always takes in the output signal of the limit switch, and when this signal is turned on,
By opening the combustion air control damper 8, a large amount of combustion air is temporarily introduced to eliminate incomplete combustion due to dripping.

Thus, the flap drop detecting flap damper of this embodiment is installed in the upper part of the charging chute, and the operation of the flap damper is converted into an electric signal by a contact switch or the like to burn the combustion air of the combustion control device 13. It is transmitted to the quantity control unit 18. Also, by adjusting the mounting position of the limit switch so that it operates when dust having a certain volume or more passes, it becomes possible to detect the drop of dust.

According to this embodiment, the measuring flap damper 6
By constantly calculating the heat input based on the waste weight detection result by the operator and the waste quality set by the operator, the combustion load set value input by the operator has been conventionally assumed to be the actual waste input and controlled. It is possible to carry out fine combustion control according to the amount of waste input. Further, the combustion air amount control unit 18 can operate the combustion air control damper 8 in advance by taking in the outputs of the measurement flap damper 6 and the drop drop detection flap damper 7 at the time of a sudden load change. It is possible to prevent the generation of CO and CO.

Further, according to the present embodiment, in the fluidized bed refuse incinerator, the weight of the supplied refuse can be continuously measured in real time by the measuring flap damper having a simple structure.
The combustion control can be accurately performed. The volume and weight of dust is detected by the flap damper, which is less susceptible to dust and dirt on the dust throw chute, enabling highly reliable dust detection over a long period of time, eliminating the need for sensor maintenance and cleaning. Becomes Further, by using the flap damper opening-dust weight characteristic to detect the dust weight, the flap damper can be used as a weighing instrument and the cost of the device can be reduced.

In this embodiment, it is preferable to provide a stopper for stopping the measuring flap damper when there is no load. 11, 12 and 13 are explanatory views showing another embodiment of the present invention. In this embodiment, when the dust accumulated on the flap damper reaches a set weight by adjusting the counterweight of the weighing flap damper, the opening operation is performed, and the operation of the flap damper is detected by a limit switch or the like. is there.

The feature of this embodiment is that since the dust is put into the incinerator in a batch manner, the amount of combustion air is only when the flap damper is opened as shown in FIGS. 12 and 13. Is to control. In this case, since the weight of dust at the time of fuel injection is almost constant and the control parameter can be predicted, control is easy. Further, according to the experiments conducted by the present inventors, it has been found that the combustion is slower when the refuse is thrown in rather than throwing it into pieces, and the generation of nitrogen oxides can be further suppressed. Therefore, it is also a measure for the environment.

FIG. 14 is a view showing a metering flap damper according to another embodiment of the present invention, and FIG. 15 is a sectional view taken along line XV-XV of FIG. In the present embodiment, the flap damper, which is a dust detection unit, is composed of conical rods arranged in strips, and the volume of dust is measured based on the number of conical rods that have operated during passage of dust. According to the present embodiment, the combined use of the flap damper composed of conical rods arranged in a strip shape and the weighing flap damper makes it possible to calculate the specific weight of the waste, and thus the actual fuel amount can be measured with higher accuracy. Automatic combustion control can be expected.

[0035]

According to the invention described in claim 1 of the present application, by providing the measuring flap damper at the inlet of the charging chute, the dust introduced into the incinerator through the charging chute can be measured in real time. Therefore, based on this, the amount of combustion air to the incinerator is adjusted to enable stable combustion without generation of pollutants.

According to the second aspect of the present invention, the counterweight of the weighing flap damper is made heavier by a predetermined weight than the flap plate, and the flap-shaped plate is formed when dust having a certain weight or more is accumulated on the flap damper. By making it open, in addition to the effects of the invention described above, combustion control is facilitated and the generation of nitrogen oxides can be further suppressed by slow combustion.

According to the invention of claim 3 of the present application, the flap plate of the measuring flap damper is divided into a plurality of strips,
Since each strip flap plate is provided with a rotation angle transmitter, the specific weight of the dust to be thrown in can be calculated, so that more accurate combustion control can be performed. According to the invention of claim 4 of the present application, since a falling drop detection flap damper having a predetermined clearance with respect to the inner wall surface of the charging chute is provided in the wake of the measurement flap damper, a large amount of dust is collected within a short time. It is possible to detect when something is dropped.

According to the invention of claim 5 of the present application, the opening amount of the measuring flap damper is detected, and the dust input weight is calculated from the detected value and the previously determined relation between the measuring flap damper opening amount and the dust weight. Then, by controlling the amount of combustion air introduced into the incinerator based on the weight of the refuse charged, stable combustion can be realized and the generation of nitrogen oxides and CO ₂ can be suppressed.

According to the invention of claim 6 of the present application, the product of the obtained amount of refuse input and the heat value of the preselected waste is regarded as a measured value of the input fuel amount, and the incinerator is based on the input fuel amount. By controlling the amount of combustion air introduced into the chamber, more stable combustion control becomes possible, and the generation of nitrogen oxides, CO _2, etc. can be suppressed more effectively. Claim 7 of the present application
According to the described invention, when the metering flap damper does not operate for a predetermined opening or more for a predetermined time or more, it is determined that dust has run out, and based on this, by controlling the combustion air amount to the incinerator, the furnace It is possible to prevent the temperature of the internal air from lowering, and particularly to suppress the generation of CO due to incomplete combustion.

According to the invention of claim 8 of the present application, when it is detected that a large amount of dust has been supplied in a short time by the stray drop detection device, the amount of combustion air introduced into the incinerator is temporarily changed. In this case, the incomplete combustion can be suppressed and the generation of pollutants can be effectively prevented.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a dust supply measuring device according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a combustion control method according to an embodiment of the present invention.

FIG. 3 is an explanatory view of a measuring flap damper.

FIG. 4 is an explanatory view of a measuring flap damper.

FIG. 5 is a view showing an operation of a measuring flap damper.

FIG. 6 is a view showing a principle of actual fuel measurement of the measurement flap damper.

FIG. 7 is an explanatory view of a fluff drop detection flap damper.

FIG. 8 is an explanatory view of a fluff drop detection flap damper.

FIG. 9 is a view showing the operation of a flap drop detection flap damper.

FIG. 10 is a view showing the operation of the flap detection flap damper.

FIG. 11 is a diagram showing another embodiment.

FIG. 12 is a view showing the operation of a weighing flap damper according to another embodiment.

FIG. 13 is a view showing the operation of a weighing flap damper according to another embodiment.

FIG. 14 is an explanatory view showing another embodiment.

FIG. 15 is an explanatory view showing another embodiment.

FIG. 16 is an explanatory diagram of a conventional technique.

FIG. 17 is an explanatory view of a conventional technique.

[Explanation of symbols]

 1 ... Input hopper, 2 ... Municipal waste, 3 ... Transfer screw,
4 ... Drum feeder, 5 ... Input chute, 6 ... Weighing hula
Up damper, 7 ... Flapping drop detection flap damper, 8 ... Burn
Baking air control damper, 9 ... Air diffuser, 10 ... Flow
Material, 11 ... O ₂Sensor, 12 ... Fluidized bed incinerator, 13
... Combustion control device, 14 ... Combustion load input section, 15 ... Waste material
Input unit, 16 ... Heat input calculation unit, 17 ... O₂Control unit, 18
... Combustion air amount control unit, 19 ... O₂Sensor, 20 ... Combustion
Air flow sensor output, 21 ... Rotation angle detector, 22 ... Garbage
Input area, 23 ... Waste area, 34 ... Flap damper
Opening angle-waste weight characteristic curve, 25 ... Waste weight-actual fuel amount characteristic
Sex line, 26 ... limit switch, 27 ... flap damper
Stop area, 28 ... Flap damper operating area, 29 ... Dosa
Drop level, 30 ... Limit switch OFF, 31
… Limit switch ON, 32… Counterway
G, 33 ... Limit switch, 34 ... Conical rod.

 ─────────────────────────────────────────────────── ─── Continued Front Page (72) Inventor Shigemi Ono 6-9 Takaracho, Kure City, Hiroshima Prefecture Babcock Hitachi Ltd. Kure Factory (72) Yoshiyuki Takasugi 6-9 9 Takaracho, Kure City, Hiroshima Prefecture Babcock Hitachi Ltd. Kure Factory

Claims (8)

[Claims] 1. A waste supply device in which waste received by a hopper is transferred by a screw and introduced into an incinerator through a charging chute, and the charging chute inlet is arranged to receive the waste transferred by the screw. A measurement flap damper having a flap-shaped plate and a counterweight that balances the moment with the flap-shaped plate is provided,
A refuse supply and measurement device characterized in that a rotation angle transmitter is provided on a rotation shaft of the measuring flap damper. 2. The counterweight of the weighing flap damper is made heavier by a predetermined weight than the flap-shaped plate, and the flap-shaped plate is opened when dust having a certain weight or more is accumulated on the flap damper. The garbage supply measuring device according to claim 1, which is characterized in that. 3. The refuse supply and measurement device according to claim 1, wherein the flap-shaped plate is divided into a plurality of strips, and each strip-shaped flap plate is provided with a rotation angle transmitter. 4. The throw-in chute so that the dust below the rated amount does not touch the dust when it passes through the throw-in chute in the wake of the metering flap damper, or a relatively small opening is shown even if it touches the dust. The dust supply measuring device according to any one of claims 1 to 3, further comprising a flap-like plate having a predetermined clearance with respect to the inner wall surface of the device. 5. A combustion control method using the dust supply measuring device according to claim 1, wherein an opening of the metering flap damper is detected, and the detected value and a metering flap obtained in advance are detected. Combustion using a dust supply measuring device characterized in that the dust input weight is obtained from the relationship between the damper opening and the dust weight, and the amount of combustion air introduced into the incinerator is controlled based on the dust input weight. Control method. 6. The product of the amount of dust input based on the opening of the measuring flap damper and the preset amount of heat generated by the dust per unit weight is regarded as the measured value of the amount of input fuel,
The combustion control method using a refuse supply measuring device according to claim 5, wherein the amount of combustion air introduced into the incinerator is controlled based on the input fuel amount. 7. The method is characterized in that when the metering flap damper does not operate for a predetermined opening or more for a predetermined time or more, it is determined that the dust has run out, and based on this, the amount of combustion air introduced into the incinerator is reduced. A combustion control method using the refuse supply measuring device according to claim 5 or 6. 8. A combustion control method using the refuse supply measuring device according to claim 4, wherein the incinerator is detected when a large amount of refuse is detected within a short period of time by the spillage detecting device. A combustion control method using a dust supply measuring device, characterized in that the amount of combustion air introduced into a furnace is temporarily increased.