JPH036407B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Field of Application) The present invention relates to a control device for inputting incineration materials to a continuous auxiliary combustion type incinerator that performs batch treatment of incineration materials.

(Prior art) Conventionally, natural combustion type incinerators have adopted a method of detecting the outlet oxygen concentration, outlet gas temperature, etc., and feeding the materials to be incinerated accordingly. In general, incineration materials are thrown in at regular intervals.

(Problems to be Solved by the Invention) As described above, in the continuous auxiliary combustion type incinerator, the materials to be incinerated are charged at regular intervals, and therefore there are the following problems. That is, the incineration efficiency was poor, and the combustion conditions varied significantly due to differences in the characteristics of the combustible materials. For example, (1) If the interval between feeding the incinerated material is too long, fuel consumption increases and efficiency decreases.

(2) If the feeding interval is too short, the heat load inside the incinerator will be excessive, resulting in insufficient air and deterioration of combustion conditions.

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, it is an object of the present invention to provide a charging control device for a continuous auxiliary combustion type batch processing incinerator that can perform optimal charging control of the materials to be incinerated depending on the characteristics of the materials to be incinerated.

(Means for Solving the Problems) The present invention provides a charging control device for a constantly auxiliary batch processing incinerator, including a first detection means for detecting the incinerator outlet gas temperature, and a first detection means for detecting the incinerator outlet gas temperature. a second detection means for detecting the supply amount of the auxiliary fuel; and a second detection means for detecting the supply amount of the auxiliary fuel. The system is configured to provide a means for inputting the materials to be incinerated based on the information.

(Function) According to the present invention, since it is configured as described above,
It is possible to perform fine-grained, optimal input control of incinerated materials according to the characteristics of the incinerated materials. In other words, (1) Complete incineration of input materials can be achieved by keeping the heat load inside the incinerator constant.

(2) By keeping the temperature inside the incinerator above a certain level,
It improves the ignitability of the incinerated material and prevents a sudden drop in temperature inside the furnace. Conversely, damage to the furnace wall due to overheating is reduced.

(3) By keeping the temperature inside the incinerator above a certain level,
Speeds up the combustion rate and improves the amount of incinerated material processed per unit time.

(4) By adding the next input before the combustion of the previous input is completed, there is no need to stabilize the exhaust gas because there is only auxiliary combustion, and auxiliary fuel can be saved.

(Example) Hereinafter, an example of the present invention will be described in detail with reference to the drawings.

Fig. 1 is a configuration diagram of a charging control device for a continuous combustion type batch processing incinerator showing an embodiment of the present invention, Fig. 2 is a diagram explaining the operation of the charging control device, and Fig. 3 is a diagram showing an example of the charging control device to which the present invention is applied. FIG. 4 is a plan view of the constantly auxiliary combustion type batch incinerator.

First, the configuration of a constantly auxiliary combustion type batch processing incinerator to which the present invention is applied will be explained.

In Figures 3 and 4, 1 is the main combustion chamber, 2 is the after-combustion chamber, 3 is the auxiliary combustion burner, 4, 5, 9, 14 are combustion air supply holes, 6 is the incineration material inlet, 7 is the damper, 8
10 is a fireproof damper, 10 is a hearth bottom damper, 11 is an ash discharge port, 12 is an incinerator gas outlet, and 13 is a flame detector.

As shown in Fig. 1, this incinerator consists of an upper combustion zone a, an intermediate combustion zone b, a bottom combustion zone c, and a latter combustion zone d.
and combustion air supply holes 4, 14 are provided.
From here, hot air containing excess air is supplied to the lower part while forming a cyclone flow. Air necessary for combustion of the incinerated material is also supplied to the intermediate combustion zone b and the bottom combustion zone c from the combustion air supply holes 5 and 9, respectively, to promote combustion in each combustion zone. Therefore, the bottom combustion area c
The incineration material 17 charged into the burner 17 is ignited by the residual combustion of the previous charge acting as a ignition source and the radiant heat from the auxiliary burner 3, and combustion is started. Normally, the incinerated material is completely combusted in the bottom combustion zone c, the lower part of the intermediate combustion zone, and the latter combustion zone d, but when a temporary combustion peak occurs, which is a phenomenon unique to batch incineration, the upper part of the intermediate combustion zone It plays an effective role as an area that absorbs this. That is, when a material to be incinerated with a high burning rate or a material with a large calorific value per unit weight is input, the flame or unburned gas after ignition reaches the upper part of the intermediate combustion zone. where it mixes thoroughly with the cyclone airflow containing excess air from the top and the supply air which is put into a counterflow in this area,
Combustion is almost completed by changing the flow downward. When such a combustion peak occurs, gas that has been almost completely incinerated in this way and some unburned materials blown up directly from the bottom of the furnace enter into the latter combustion zone c. When the combustion is finally completed, the unburned solid particles that take time to burn due to the slow upward flow either fall to the bottom and burn again, or rise at a slower speed than the gas flow. , allow sufficient residence time. The amount of air introduced into the incinerator is designed to ensure 10% or more excess oxygen at the incinerator gas outlet 12 even during such peak combustion, and complete combustion can be achieved.

Next, the configuration of a charging control device for a continuous combustion type batch processing incinerator according to the present invention will be explained with reference to FIG.

In the figure, 17, 18, and 19 are incineration materials consisting of combustible miscellaneous solids, etc., 20 is an auxiliary fuel supply amount adjustment valve provided in an auxiliary fuel pipe line that is supplied to the auxiliary combustion burner 3,
21 is an actuator that drives the regulating valve;
2 is an auxiliary fuel flow rate detector provided in the auxiliary fuel pipe, 23 is an incinerator outlet gas temperature detector provided at the incinerator gas outlet 12, and 24 is a sensor for conveying the incinerated material to the incinerated material inlet 6 The motor, 25 is a control device, and this control device is a CPU (central processing unit).
25-1, memory 25-2, interface 2
It consists of 5-3 and 25-4.

Next, the operation of the charging control device for this continuous combustion auxiliary batch treatment incinerator will be explained with reference to FIGS. 1 and 2.

When using a constant combustion type incinerator as shown in Fig. 1, when incineration materials containing combustible miscellaneous solids and the like are put in batches, the temperature of the incinerator outlet gas is detected by a temperature detector 23. The data is read into the control device 25, and based on the data, the actuator 21 is driven and the opening degree of the auxiliary fuel supply amount adjustment valve 20 is operated to adjust the amount of auxiliary fuel supplied to the auxiliary combustion burner 3. , constant control of the incinerator outlet gas temperature. At the same time, the amount of auxiliary fuel supplied is detected by the flow rate detector 22, this detected data is read into the control device 25, and based on it, a drive signal is sent from the control device 25 to the motor 24 to drive the motor 24. Then, the next incineration material 18 is put in from the incineration material input port 6.

The state of the incinerator outlet gas temperature and auxiliary combustion amount in that case is shown in FIG.

As shown in Figure 2, when the first incineration material is introduced (time t ₀ ), the incinerator outlet gas temperature drops instantaneously due to moisture evaporation, sensible heat, decomposition heat, etc. (t 0 ). ₀ -t ₁ ), the amount of auxiliary fuel supplied increases by controlling the auxiliary fuel supply amount adjustment valve 20 based on the incinerator outlet gas temperature, and the incinerator outlet gas temperature rises to a set value, e.g., 815°C. Controlled by setting the target value.

As the next step, when the input incineration material 17 is ignited by radiation heat etc. from the auxiliary burner 3 and starts to generate heat, the incinerator outlet gas temperature shows an upward trend, and the incinerator outlet gas temperature is controlled to increase the auxiliary fuel. The amount supplied decreases rapidly (see t ₁ − t ₂ ). When the combustion progresses to a certain extent and passes its peak, the incinerator outlet gas temperature begins to decrease, so the amount of auxiliary fuel supplied begins to increase. At this time, the time when the amount of auxiliary fuel supplied exceeds a certain value, that is, the time when incineration has progressed to a certain extent (time t ₃ ), is determined by comparing the amount of auxiliary fuel supplied by the flow meter 22 and the control device 25. The control device 25 compares the supply amount of the incineration material input setting auxiliary fuel stored in advance in the memory 25-2 of
Therefore, the signal for inputting the next incineration material 18 is sent to the motor 2.
4 and drive the motor 24,
The next incineration material 18 is put into the incinerator.

Further, the setting of the time point at which the incineration material is introduced can also be performed as follows.

First, the material to be incinerated is input, that is, the motor 2
When the off signal No. 5 is read into the control device 25, the control device 25 measures time from this point on, and after a certain period of time,
The amount of auxiliary fuel supplied is read from the flow meter 22 into the control device 25, and then, the control device 25 determines whether the amount of auxiliary fuel supplied exceeds a set value. Therefore, if the supply amount of auxiliary fuel exceeds a set value, the motor 25 may be driven to input the material to be incinerated. With this configuration, the characteristics of the incinerated material are constant,
In cases where the incineration materials are being thrown in one after another,
Since the determination time point can be set in advance by the time measurement of the control device 25, it is possible to perform simple control and to reduce the memory capacity of the control device.

As described above, according to the present invention, constant control of the outlet gas temperature is carried out by controlling the supply amount of the auxiliary fuel, and furthermore, by observing the fluctuation state of the supply amount of the auxiliary fuel, the next incineration material is determined. will be implemented.

Here, from the experimental data, if the amount of auxiliary fuel supplied during non-incineration, that is, when only auxiliary fuel is combusted, is 50/h, then the amount of auxiliary fuel supplied at the incineration material input setting is 35/h to 45/h. By setting h,
Ignition by residual combustion was good, and the amount of combustion at the peak time was not excessive, indicating a good condition.

Note that the present invention is not limited to the above-mentioned embodiments, and various modifications can be made based on the spirit of the present invention, and these are not excluded from the scope of the present invention.

(Effects of the Invention) As described above in detail, according to the present invention, it is possible to operate the inside of the incinerator under a constant heat load, and the fuel consumption is reduced due to the feeding interval of the incinerated material being too long. It is possible to eliminate the increase in fuel consumption and decrease in efficiency, and to effectively prevent the occurrence of excessive heat load in the incinerator, lack of air, and deterioration of combustion conditions due to the input interval of incinerated materials being too short. be able to.

In this way, it is possible to improve the incineration efficiency, and to perform optimal input control of the material to be incinerated according to the characteristics of the material to be incinerated.

[Brief explanation of drawings]

Fig. 1 is a configuration diagram of a charging control device for a continuous combustion type batch processing incinerator showing an embodiment of the present invention, Fig. 2 is a diagram explaining the operation of the charging control device, and Fig. 3 is a diagram showing an example of the charging control device to which the present invention is applied. FIG. 4 is a plan view of the constantly auxiliary combustion type batch incinerator. 1... Main combustion chamber, 2... After combustion chamber, 3... Assist burner, 4, 5, 9, 14... Combustion air supply hole,
6... Incinerator inlet, 7... Damper, 8... Fireproof damper, 10... Hearth bottom damper, 11... Ash discharge port, 12... Incinerator gas outlet, 13... Flame detector, a... ...Upper combustion zone, b...Middle combustion zone, c...
...Bottom combustion area, d...Late combustion area, 17-19...
Incineration material, 20... Auxiliary fuel supply amount adjustment valve, 21...
...Actuator, 22...Flow rate detector, 23...
... Temperature detector, 24 ... Motor, 25 ... Control device, 25-1 ... CPU (central processing unit), 25-
2...Memory, 25-3, 25-4...Interface.

Claims (1)

[Scope of Claims] 1 (a) a first detection means for detecting the incinerator outlet gas temperature; (b) a method for keeping the incinerator outlet gas temperature constant based on information from the first detection means; (c) a second detection means for detecting the supply amount of the auxiliary fuel; (d) input of the incineration material based on information from the second detection means; A charging control device for a continuous combustion type batch processing incinerator, comprising means for performing the following steps. 2. The constant auxiliary combustion type according to claim 1, characterized in that the time point at which the incineration material is introduced is set at the time when the supply amount of the auxiliary fuel once decreases, then increases, and exceeds a certain value. Batch processing incinerator input control device. 3. A patent characterized in that after a certain period of time after the incineration material is input, it is determined whether or not the amount of auxiliary fuel supplied exceeds a certain value, and if it exceeds, the incineration material is introduced. A charging control device for a constantly auxiliary combustion type batch processing incinerator according to claim 1.