JPH10253030A - Inner pressure controller for furnace - Google Patents

Abstract

PROBLEM TO BE SOLVED: To control the inner pressure of a furnace through a simple structure by regulating the r.p.m. of an induction fan such that the opening of an exhaust gas damper is regulated to a reference opening if it deviates from an allowable range at the time of controlling the r.p.m. of an induction fan through an r.p.m. regulation means. SOLUTION: An r.p.m. regulation means 13 in an inner pressure controller 10 for furnace comprises a section 13a for deciding whether the r.p.m. of an induction tan 4 is varied or not and determining the varying direction, if necessary, based on the information of a decision whether the opening of an exhaust gas damper 3 is within an allowable range or not made at the opening decision section 12c of a damper opening regulation means 12, and a section 13b for controlling a frequency control mechanism 14 controlling the r.p.m. of an induction motor driving the induction fan 4. When a decision is made that the opening deviates from an allowable range, the direction for varying the power supply frequency is determined depending on the direction deviating the allowable range and the direction for increasing/decreasing the r.p.m. is designated for the frequency control mechanism 14 by the decision section 13a thus regulating the r.p.m. of the induction fan 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an in-furnace pressure control device, and more particularly, to an exhaust gas passage for guiding exhaust gas from a waste incinerator to a chimney, an exhaust gas damper and an induction blower provided in this order. A furnace pressure detecting means for detecting a furnace pressure of the processing furnace, and a damper opening for adjusting an opening of the exhaust gas damper within an allowable range so that a furnace pressure detected by the furnace pressure detecting means becomes a target furnace pressure. The present invention relates to a furnace pressure control device provided with adjusting means and rotation speed adjusting means for controlling the rotation speed of the induced blower.

[0002]

2. Description of the Related Art In a conventional waste treatment facility, it is necessary to cope with a wide range of induced air flow in order to control the internal pressure of the waste treatment furnace. The flow rate is adjusted by adjusting the temperature and changing the rotation speed of the induction blower.If the furnace internal pressure changes so that the opening degree of the exhaust gas damper is out of the set allowable range, the allowable range is set. As a supplement to the control of the furnace pressure in the outer region, a measure is taken to change and adjust the rotation speed of the induction blower to further change the amount of induced air. The opening degree of the exhaust gas damper is adjusted by using the furnace internal pressure as a feedback signal, and the control signal for the induction blower for this purpose changes and adjusts the rotation speed stepwise. That is, as shown in FIG. 4, an exhaust gas damper 3 and an induction blower 4 are provided in order in an exhaust gas path 2 that guides exhaust gas from a waste treatment furnace 1 to a chimney 5. A damper opening adjusting unit 12 having an opening setting unit 12a for controlling the opening of the internal pressure detecting unit 11 based on a furnace pressure (P) detected by a furnace pressure sensor 11a provided in the waste treatment furnace 1 based on a furnace pressure (P). The opening is adjusted by. The opening (Z) of the exhaust gas damper 3 is detected by an opening detector 12b of the damper opening adjuster 12, and
It is determined by the opening degree determination unit 12c whether or not it is within an allowable range,
When the discriminating unit 13a detects the deviation from the allowable range, the output frequency (F) from the inverter control mechanism 14 provided in the rotation speed setting unit 13b of the rotation speed adjusting unit 13 for controlling the induction motor that drives the induction blower 4 is output. ) Is changed stepwise so as to maintain the opening (Z) within the allowable range. This furnace pressure control is performed, for example, in a procedure as shown in FIG. In other words, detecting the furnace inner pressure (P) in a furnace pressure detection means 11 <Step 2-※ 1>, is compared with the target furnace pressure (P _S) at the degree of opening setting unit 12a <Step 2-※ 2>. In the degree of opening setting unit 12a, based on a comparison result in <Step 2-※ 2>, furnace pressure (P) is lower than the target furnace pressure (P _S) is the opening of the exhaust gas damper 3 Adjust to the decreasing side <Step 2- * 3.1>,
When the furnace pressure (P) is higher than the target furnace pressure (P _S) adjusts the opening degree of the exhaust gas damper 3 to the side of increase <Step 2-※ 3.2>. The above is automatically executed based on the detection result of the furnace internal pressure (P) in the opening degree setting unit 12a. Further, the opening degree (Z) of the exhaust gas damper 3 is detected by the opening degree detecting unit 12b.
4> The opening degree (Z) is compared with the allowable range of the opening degree set by the opening degree determining section 12c, and the results of <Step 2- * 5> and <Step 2- * 5> are determined by the determining section 13a. And the opening (Z) is the lower limit opening (Z _l ) of the allowable range.
If it is less than 1, the rotation speed setting unit 13b reduces the rotation speed (N) of the induction blower 4 by a predetermined change amount (ΔN) <Step 2- * 6.1>, and the opening degree (Z) is equal to the allowable value. If it exceeds the upper limit opening (Z _u ) of the range, the rotation speed (N) of the induction blower 4 is increased by a predetermined change amount (ΔN) (Step 2- * 6.2). The above cycle is repeated at predetermined time intervals. For example, when the allowable range of the opening degree of the exhaust gas damper is set to 35% to 65%, and the induction blower is controlled by an inverter to be driven in a frequency range of 10 Hz to 60 Hz, If the opening degree of the damper exceeds 65%, stepwise control is performed such that the output frequency of the inverter control mechanism 14 is increased by, for example, 5 Hz. When the opening is less than 35%, the output frequency of the inverter control mechanism 14 is set to, for example, 5 Hz.
Decrease. As a result, the rotation speed (N) of the induction blower 4
Is adjusted stepwise in about 10 seconds. The detection of the opening degree of the exhaust gas damper is repeated, for example, at intervals of 10 seconds.

[0003]

In the conventional control of the furnace pressure, the furnace pressure (P), the opening degree (Z) of the exhaust gas damper 3, and the rotation speed adjusting means 13 provided for controlling the induction blower are controlled. The output frequency (F) of the provided inverter control mechanism 14 and the rotation speed (N) of the induction blower 4 show the behavior as shown in FIG. 6 when, for example, the furnace pressure changes. That is, the opening degree (Z) of the exhaust gas damper 3 changes in response to a change in the furnace pressure (P). Once the opening (Z) detected at a predetermined time interval exceeds the upper limit of the allowable range, the rotational speed (N) of the induced blower 4 is determined to be larger than the opening (Z). The rotation speed (N) is not changed and adjusted until it becomes lower than the lower limit of the range. As a result, if the rotation speed (N) is excessive, the furnace pressure (P) continues to decrease until the opening (Z) becomes less than the lower limit of the allowable range. As described above, the rotation speed of the induction blower is changed and adjusted only to maintain the opening degree of the exhaust gas damper within an allowable range. As a result, a single change width of the opening degree of the exhaust gas damper is reduced. , Spread throughout its tolerances. Accordingly, the range of the fluctuation of the furnace pressure is also widened, which results in an undesirable result for the stable control of the furnace pressure. Further, if the change width of the output frequency (F) is large and the opening degree (Z) of the exhaust gas damper 3 exceeds one of the allowable ranges, the output frequency (F) changes with the change of the output frequency (F). The rotation speed of the induced blower becomes excessive, and the excessive suction is continued, so that the limit of the allowable range in the opposite direction is approached in a short time. Therefore, in this case, even if the furnace pressure returns to the original value, the control for changing the rotation speed in the reverse direction again does not function within the allowable range, so that the rotation of the induction blower until the opposite limit is reached. Hunting may be caused because the number is not adjusted and changed.
Also, if the degree of change in the number of revolutions is too low,
As shown in FIG. 7, as a result of the opening degree of the exhaust gas damper being settled close to the limit on the side deviating from the permissible range, the furnace pressure thereafter slightly changes to the deviated side. Even if shown, the rotation speed must be changed again in the same direction. This is the same when the furnace pressure changes over a wide range. Moreover, the rotation speed is changed in the direction of returning the rotation speed when the damper opening degree deviates to a side opposite to the side deviating from the allowable range, and as a result, the furnace internal pressure is greatly changed. There is a problem regarding the stability of the internal pressure control. Further, when the rotation speed changes, the noise generated by the induction blower increases, and this noise increases as the change width increases. Further, if the step width of the change of the rotation speed is increased, the hunting phenomenon is likely to occur as described above, and the noise generated at that time also increases. In other words, if the rotational speed changes stepwise, there is a problem that a transient change in the furnace pressure is caused, which adversely affects the stability of combustion. Further, when the rotational speed is changed and adjusted, noise is reduced. There is a problem that becomes large. For example, if the damper suddenly fluctuates upward or downward on the upper limit or lower limit of the damper opening due to the change in the dust quality, the difference in control characteristics between the damper and the electric motor driving the induction blower causes a delay. The follow-up of the large damper is insufficient, so that the rotation speed of the electric motor is repeatedly changed, and high noise is repeatedly generated. When the damper suddenly moves downward or upward at the upper or lower limit of the damper opening, the motor rotation is continued until the damper changes from the upper or lower limit of the damper opening to the lower or upper limit. Since the adjustment of the change in the number is not performed and the change width of the damper opening is large, the response delay becomes large, which tends to cause unstable furnace pressure and hunting phenomenon of the control of the damper and the induction blower.
Therefore, a furnace pressure control device of the present invention solves the above-mentioned problems, and provides a control means capable of stably controlling the furnace pressure with a simple configuration while preventing noise. Aim.

[0004]

[Means for Solving the Problems]

[First characteristic configuration] A first characteristic configuration of the furnace internal pressure control device of the present invention for the above purpose is as described in claim 1, wherein the rotational speed adjusting means for controlling the rotational speed of the induction blower is provided for exhaust gas. When the opening degree of the damper deviates from the allowable range, the rotation speed adjusting means adjusts the opening degree of the exhaust gas damper to a reference opening degree set within the allowable range, so that the induction blower is The point is that the number of rotations is adjusted. [Operation and Effect of First Characteristic Configuration] According to the first characteristic configuration, the opening degree of the exhaust gas damper can be controlled stably while expanding the time interval for changing and adjusting the rotation speed of the induction blower. That is, when the opening degree of the exhaust gas damper deviates from an allowable range, the opening degree of the exhaust gas damper is adjusted to a reference opening degree set within the allowable range.
Since the rotation speed of the induction blower is adjusted, after the change adjustment of the rotation speed of the induction blower, the opening degree of the exhaust gas damper is settled at a position having a margin in both the opening and closing directions. Therefore, since there is a margin on both sides until the opening degree deviates from the permissible range, it is possible to prevent a request for a change in the rotation speed immediately due to a change in the furnace pressure, and a frequency of the change adjustment of the induction fan rotation speed. Can be reduced. Of course, the hunting phenomenon can be reliably prevented. As a result, it has become possible to stably control the furnace pressure with a simple configuration while reducing the frequency of changing and adjusting the induction fan rotation speed to prevent noise.

[Second characteristic configuration and operation and effect] According to the second characteristic configuration of the furnace pressure control device of the present invention, the allowable range in the first characteristic configuration is defined as the exhaust gas damper. The point is that the opening is in the range of the opening corresponding to the linear operation region. In this case, the opening and closing control of the exhaust gas damper becomes easy. As a result, the furnace pressure can be more stably controlled with a simple configuration.

[Third characteristic configuration and operation and effect] The third characteristic configuration of the furnace pressure control device according to the present invention is the same as the first characteristic configuration or the second characteristic configuration in the second characteristic configuration. The degree of opening is set at or near the center of the allowable range of the degree of opening of the exhaust gas damper, thereby reducing the frequency of requests for adjusting the rotation speed of the induction blower and reducing the hunting phenomenon. It can be prevented reliably. In other words, the opening degree of the exhaust gas damper that stabilizes after changing and adjusting the rotation speed of the induction blower has a margin of approximately the same width on both sides of the opening and closing, and the furnace pressure after the stabilization rises and falls. , There is a margin until the opening deviates from the allowable range next time. As a result, it is easy to stably control the furnace pressure with a simple configuration while preventing noise.

[Fourth characteristic configuration and operation and effect] Further, a fourth characteristic configuration of the furnace internal pressure control device of the present invention is the rotation speed adjustment in any of the first to third characteristic configurations as described in claim 4. Means are provided with an inverter control mechanism, the output frequency from the inverter control mechanism, the exhaust gas damper,
It is configured to change within the range of the rate of change determined from the characteristic of following the control signal from the damper opening adjustment means. Can be prevented from changing, so that the control becomes stable. This is whether the rotation speed of the induction blower can be changed and adjusted in cooperation with the opening degree changing operation of the exhaust gas damper. That is, the control response delay of the damper mechanism is generally large, and the exhaust gas damper is detected by detecting the furnace internal pressure.
Even in the case of the D control, if the rotation speed of the induction blower is fast, the undershoot is likely to occur due to a response delay. If the control response speed is increased to prevent this, overshoot is likely to occur. As a result, the opening degree of the exhaust gas damper may deviate from the allowable range before settling. Therefore, the changing speed of the rotation speed is matched with the response speed of the exhaust gas damper. By doing so, it is possible to reduce the number of requests to adjust the rotation speed while gradually changing the rotation speed of the induction blower. Moreover, the noise level can be reduced by slowing down the speed of change of the rotation speed. As a result, it is possible to more stably control the furnace internal pressure with a simple configuration while preventing noise more reliably.

[0008]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One example of an embodiment of the furnace internal pressure control device of the present invention will be described below with reference to the drawings. Note that the same elements as those described in the related art, the values of the phenomena, and the elements having the same functions are denoted by the same reference numerals as those in FIGS. Parts are omitted.

FIG. 1 shows an example in which the furnace pressure control device of the present invention is applied to a waste incineration plant. The configuration from the waste incinerator, which is an example of the waste treatment furnace 1, to the chimney 5 is the same as that shown in FIG. The furnace pressure control device 10 includes a furnace pressure detecting unit 11 that detects a furnace pressure (P) of the waste incinerator 1,
It comprises damper opening adjusting means 12 for adjusting the opening of the exhaust gas damper 3 and rotation speed adjusting means 13 for adjusting the rotation speed of the induction blower 4.

The rotation speed adjusting means 13 receives information on whether or not the opening (Z) of the exhaust gas damper 3 determined by the opening determining section 12c of the damper opening adjusting means 12 is within an allowable range. Determining unit 13 for determining whether to change and adjust the rotation speed of the induction blower 4 and determining the change direction;
a rotation speed setting unit 1 including a stationary Leonard frequency control mechanism 14 as an inverter control mechanism for controlling the rotation speed (N) of the induction motor that drives the induction blower 4.
3b.

When the determination unit 13a determines that the opening (Z) is out of the allowable range, the change direction of the power supply frequency (F) is determined according to the direction deviating from the allowable range. The direction of increase or decrease of the rotation speed (N) of the determination unit 13a is determined by the frequency control mechanism 14 of the rotation speed setting unit 13b.
To instruct. The frequency control mechanism 14 is provided with the determination unit 1
3a, the power supply frequency (F) is set to, for example, 1H per 10 seconds in accordance with the direction of increase or decrease of the rotation speed (N).
z is changed. The change of the power supply frequency (F) is based on the fact that the opening (Z) of the exhaust gas damper 3 detected by the opening detecting section 12b of the damper opening adjusting means 12 is equal to the reference opening (Z _S ).
Until it reaches.

The furnace pressure control in the furnace pressure control apparatus of the present invention is performed, for example, according to the procedure shown in FIG. In other words, detecting the furnace inner pressure (P) in a furnace pressure detection means 11 <Step 1-※ 1>, is compared with the target furnace pressure (P _S) at the degree of opening setting unit 12a <Step 1-※ 2>. In the degree of opening setting unit 12a, based on a comparison result in <Step 1-※ 2>, when the furnace pressure (P) is lower than the target furnace pressure (P _S) is the exhaust gas damper 3 opening ( adjust the Z) to reduce side <step 1-※ 3.1>, when the furnace pressure (P) is higher than the target furnace pressure (P _S), the exhaust gas damper 3 opening (Z ) Is adjusted to the increasing side (step 1- * 3.2). The above is automatically performed by the opening setting unit 12.
This is executed based on the detection result of the furnace internal pressure (P) in a.
Further, the opening degree (Z) of the exhaust gas damper 3 is detected by the opening degree detecting section 12b (Step 1- * 4), and the opening degree (Step 1- * 4) detected by the rotation speed setting section 13b (Step 1- * 4). It is determined whether or not Z) has reached the reference opening (Z _S ) (Step 1- * 5). Here, when the opening (Z) reaches the reference opening (Z _S ), the later-described rotation speed change instruction to the rotation speed setting unit 13b is canceled and <Step 1- *
6>, and return to <Step 1- * 1>. Further, the opening (Z) detected by the opening detecting unit 12b in <Step 1- * 5> is compared with the allowable range of the opening in which the opening (Z) is set by the opening determining unit 12c. Then <Step 1- *
7> As a result of <Step 1- * 7>, if the opening (Z) is smaller than the lower limit opening (Z _l ) of the allowable range, the induction fan 4 is instructed to the rotation speed setting unit 13b. An instruction to decrease the rotation speed (N) is issued <Step 1- * 8.
1>, based on the instruction received from the determination unit 13a in <Step 1- * 8.1>, the rotation speed setting unit 13b reduces the 1 Hz power supply frequency (F) for a predetermined time <Step 1- * 9. 1>. On the other hand, as a result of <Step 1- * 7>, the opening (Z) is set to the upper limit opening (Z _u ) of the allowable range.
Is exceeded, an instruction to increase the rotation speed (N) of the induction blower 4 is issued <Step 1- * 8.2>, and the instruction received from the determination unit 13a in <Step 1- * 8.2>. , The rotation speed setting unit 13b sets 1 Hz for a predetermined time.
Increase power supply frequency (F) <Step 1- * 9.
2>. The above cycle is repeated for furnace pressure control.

For example, as shown in FIG. 3, the lower limit opening (Z _l ) is 35% and the upper limit opening (Z _u ) is 65%.
The allowable range of the opening degree (Z) of the exhaust gas damper 3 is set to 35 to 65% of the 30% width, and the reference opening degree (Z
_S ) is set to 50%, and the output frequency (F) is inverter-controlled by using a stationary Leonard type frequency control mechanism as the inverter control mechanism 14 in the rotation speed setting unit 13b of the rotation speed adjusting means 13 of the induction blower 4. Then 10
And the opening (Z) of the exhaust gas damper deviates from the upper limit opening (Z _u ) to 6
If it exceeds 5%, rotation speed control is performed such that the output frequency of the frequency control mechanism 14 is increased by, for example, 1 Hz for 10 seconds. Then, deviating said opening (Z) from said lower opening (Z _l), if less than 35%, reduces 1Hz to the output frequency of the frequency control mechanism 14 (F), for example, 10 seconds. Then, the change of the output frequency (F) is continued until the opening (Z) of the exhaust gas damper 3 reaches the reference opening (Z _S ). As a result, the rotation speed (N) of the induction blower 4 changes at a speed that allows a delay in following the opening (Z) of the exhaust gas damper 3, and the opening (Z) in the previous period. Is the reference opening (Z
The rotation speed (N) of the induction blower 4 is changed and adjusted until reaching _S ). Therefore, even if the delay in following the opening degree (Z) of the exhaust gas damper 3 becomes large, it is possible to avoid an overshoot of control due to the delay.

Next, another embodiment of the present invention will be described. <1> In the above embodiment, an example was shown in which the furnace pressure control device of the present invention was applied to a waste incineration facility having a waste incinerator 1, but the applied facility was a combustion space in the furnace. The present invention can be applied to any waste treatment facility as long as it controls the internal pressure. For example, it can be suitably used for a waste pyrolysis furnace, a waste melting furnace, and the like. Further, the present invention is not limited to the type of furnace, and in the case of a waste incinerator, the present invention can be applied to a stoker type, a rotary drum type (for example, a rotary kiln furnace), a fluidized bed type, and other combustion furnaces. Is In the form of <2> above-35% the lower limit opening (Z _l) of the degree of opening of the exhaust gas damper 3 (Z), the upper limit opening (Z _u) 65%, the reference opening (Z _S ) is set to 50%, and the allowable range is set to an opening of 35 to 65%, but the lower limit opening (Z _l ) and the upper limit opening (Z
_u ) is set according to the characteristics of the damper mechanism.
This shows an example in which a region where the control characteristic is linear is used, and depending on the characteristics of the damper mechanism, it is possible to set an allowable range including a non-linear region. The reference opening (Z _S ) also uses the median value of the linear region, and is set so as not to cause a difference in controllability on both sides of the reference opening (Z _S ). Depending on the control characteristics of the blower 4, if it is more convenient to set the reference opening (Z _S ) in one of the upper and lower directions, it is so set. Although the control width is set to 30%, this is also set according to the characteristics of the damper mechanism and further according to the characteristics of the induction blower 4 and its driving motor, and even if the control width is 40%. And may be 20%. <3> In the above-described embodiment, an example has been described in which the damper opening adjustment unit 12 is configured by the opening detection unit 12b, the opening determination unit 12c, and the damper opening setting unit 12a. This configuration is merely an example, and any configuration may be used as long as the damper opening is adjusted in accordance with the furnace pressure and the induction capacity of the induction blower. <4> In the above embodiment, the rotation speed adjusting means 13
Is constituted by the determination unit 13a and the rotation speed setting unit 13b, but this configuration is an example, and the driving of the induction blower 4 is controlled so that the opening degree (Z) of the exhaust gas damper 3 and It does not matter what the configuration is if it is configured to work together without inconsistency. For example, in the above example, an example is shown in which the drive motor of the induction blower 4 is an induction motor, and the rotational speed setting unit 13b is provided with a frequency control mechanism of a stationary Leonard system as the inverter control mechanism 14; The rotation speed setting unit 13b
May be a drive speed control mechanism of another type. Further, the drive motor may be a DC motor or may be controlled by a power supply voltage.

In the claims, reference numerals are provided for convenience of comparison with the drawings, but the present invention is not limited to the configuration shown in the accompanying drawings.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing an application example of a furnace pressure control device of the present invention.

FIG. 2 is a flowchart showing an example of a control procedure of the furnace pressure control device shown in FIG.

FIG. 3 is an explanatory diagram showing an example of a control response diagram for the control procedure shown in FIG. 2;

FIG. 4 is an explanatory view showing an example of a conventional furnace pressure control device.

FIG. 5 is a flowchart showing an example of a conventional control procedure.

FIG. 6 is an explanatory diagram showing an example of a control response diagram for the control procedure shown in FIG. 5;

FIG. 7 is an explanatory diagram showing another example of a control response diagram for the control procedure shown in FIG. 5;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Waste treatment furnace 2 Exhaust gas path 3 Exhaust gas damper 4 Induction blower 5 Chimney 11 Furnace pressure detection means 12 Damper opening degree adjustment means 13 Revolution number adjustment means 14 Inverter control mechanism

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification code FI F23L 17/16 609 F23L 17/16 609M G05D 16/20 G05D 16/20 A H02P 7/63 302 H02P 7/63 302D // F16K 31/04 F16K 31/04 K

Claims (4)

[Claims] An exhaust gas path (2) for guiding exhaust gas from a waste treatment furnace (1) to a chimney (5) is provided with an exhaust gas damper (3) and an induced blower (4) in order. Furnace pressure detecting means (1) for detecting the furnace pressure of the processing furnace (1);
1) and a damper opening adjusting means (12) for adjusting the opening of the exhaust gas damper (3) within an allowable range so that the furnace pressure detected by the furnace pressure detecting means (11) becomes a target furnace pressure. ), And a rotation speed adjusting device (13) for controlling the rotation speed of the induction blower (4), wherein the rotation speed adjusting device (13) is provided with the exhaust gas damper (13). When the opening degree of 3) deviates from the allowable range, the opening degree of the exhaust gas damper (3) is adjusted to a reference opening degree set within the allowable range. A furnace pressure control device configured to adjust the rotation speed. 2. The furnace pressure control device according to claim 1, wherein the allowable range is a range of an opening corresponding to a linear operation region of the exhaust gas damper (3). 3. The furnace pressure control device according to claim 1, wherein the reference opening is an opening set at the center of the allowable range or in the vicinity thereof. 4. An inverter control mechanism (14) is provided in said rotation speed adjusting means (13), and an output frequency from said inverter control mechanism (14) is
The exhaust gas damper (3) is configured to change within a range of a change rate determined from a characteristic of following a control signal from the damper opening adjusting means (12).
The furnace pressure control device according to any one of claims 1 to 3.