JP3787901B2 - Device for calculating the amount of coal output during normal shutdown of a coal fired boiler - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a coal output calculation device when a coal fired boiler is normally stopped.
[0002]
[Prior art]
In general, in the case of a coal fired boiler, as shown in FIG. 3, the coal stored in the coal bunker 1 is put into a coal grinding mill 4 by a coal feeder 3 driven by a driving device 2 such as a motor. The pulverized coal pulverized in the mill 4 is conveyed by air to the burner 6 through the pulverized coal pipe 5 and burned in the furnace 8 of the boiler 7.
[0003]
In the figure, 9 is a coal gate that is opened and closed by a driving device 10 such as a motor.
[0004]
Since the amount of coal (pulverized coal) supplied from the mill 4 to the furnace 8 of the boiler 7 cannot be directly measured, a load cell that does not show the weight of coal currently on the coal feeder 3 is shown. And the rotational speed of the driving device 2 of the coal feeder 3 is measured, and the product of these is defined as the amount of coal supplied from the coal feeder 3 to the mill 4. The coal output is expected to be supplied into the furnace 8 of the boiler 7.
[0005]
Moreover, the said mill 4 is normally provided with multiple units | sets (for example, 6 units | sets) with respect to the one boiler 7, The total amount of coal output of each mill 4 at the time of the steady operation of the boiler 7, The fuel flow rate command based on the boiler load command (MWD) is compared, a coal feed amount command to each coal feeder 3 is obtained according to the comparison result, and each coal feeder 3 is determined based on the coal feed command. It comes to perform control.
[0006]
On the other hand, for example, when one mill 4 is normally stopped, first, the coal gate 9 of the coal bunker 1 corresponding to the mill 4 is closed, and the coal remaining on the coal feeder 3 is put into the mill 4. The coal feeder 3 is stopped, but if the coal remains in the mill 4, the coal remaining in the mill 4 may ignite, so after the coal feeder 3 is stopped, It is necessary to continue the operation of the mill 4 for a required time and to perform a process of discharging the coal remaining in the mill 4 into the furnace 8.
[0007]
However, as described above, when the coal gate 9 is closed and the coal feeder 3 is stopped in order to normally stop one of the mills 4, the coal supply amount becomes zero at that point. The coal output from the mill 4 has a pulverization delay, and after the coal feeder 3 stops, the coal output continues from the inside of the mill 4 in order to empty the inside of the mill 4, and thus exceeds the fuel flow rate command. Excessive coal will be supplied into the furnace 8 of the boiler 7, and there is a risk that the exhaust gas O ₂ will decrease or the steam temperature will rise due to excessive fuel.
[0008]
For this reason, conventionally, as shown in FIG. 4, during a steady operation, the amount of coal supply 11 input from the coal feeder 3 to the mill 4 is directly output as a signal 11 ′ (switched to the b side in the figure). On the other hand, when the coal gate 9 is closed at the time of normal mill stop, a switch 36 that outputs a signal 38 of “0” output from the signal generator 37 (switched to the a side in the figure) as a signal 11 ′;
At the time of steady operation, the signal 11 ′ output from the switch 36 is output as the signal 12 as it is (switched to the b side in the figure). On the other hand, when the coal gate 9 is closed when the mill is normally stopped, the switch 36 is at that time. A switch 11 that holds the signal 11 ′ of the coal supply amount 11 immediately before becoming “0” and is output as a signal 12 representing the remaining coal amount (switched to the a side in the figure);
A timer 16 for outputting a signal 15 of “1” after elapse of a required time (t [minutes]) from the time when the coal gate switching command 14 for closing the coal gate 9 is output at the time of the mill normal stop;
At the time of steady operation, the signal 12 output from the switch 13 is output as it is as the signal 19 (switched to the b side in the figure), while the time set by the timer 16 when the coal gate 9 is closed at the time of normal mill stoppage. A switch 20 that outputs a signal 18 of “0” output from the signal generator 17 after the lapse of time as a signal 19 (switched to the a side in the figure);
When the signal 19 output from the changer 20 changes, the change in the signal 19 is followed so that a preset time delay occurs, and it is predicted that the coal is discharged from the mill 4 when the mill is normally stopped. A primary delay device 22 for outputting a coal output simulation signal 21;
During steady operation, the signal 11 'output from the switch 36 is output as it is as the coal output 23 (switched to the b side in the figure), while the primary delay device 22 is closed when the coal gate 9 is closed during normal mill stop. A coal output calculation device is constituted by a switch 39 that outputs a coal output simulation signal 21 output from No. 1 as a coal output 23 (switched to the a side in the figure).
[0009]
In the case of the conventional coal output calculation device as described above, during a steady operation, the coal supply amount 11 input from the coal feeder 3 to the mill 4 is directly output as a signal 11 ′ to the switch 39 via the switch 36. The signal 11 ′ of the coal supply amount 11 is output as the coal output amount 23 via the switch 39.
[0010]
On the other hand, in order to normally stop the mill 4, a coal gate switching command 14 for closing the coal gate 9 of the coal bunker 1 corresponding to the mill 4 is output, and when the coal gate 9 is closed, the switch 36 Since the “0” signal 38 output from the generator 37 is output as the signal 11 ′, as shown in FIG. 5, the coal supply amount signal 11 ′ is changed from x [ton / h] to “ However, when the coal gate 9 is closed when the mill is normally stopped, the switching unit 13 holds the signal 11 ′ of the coal supply amount 11 immediately before becoming “0” output from the switching unit 36 at that time. And output to the switcher 20 as a signal 12 representing the amount of remaining coal.
[0011]
When the coal gate switching command 14 is output, a signal 15 of “1” is output from the timer 16 after the required time (t [minute]) has elapsed, and the signal 12 output from the switch 13 After the time set by the timer 16 has elapsed from the state of being output as the signal 19 via the switching device 20, the switching device 20 switches to the “0” signal 18 output from the signal generator 17. Output to the delay unit 22, and in the primary delay unit 22, the change in the signal 19 output from the switcher 20 is made to follow a preset time delay so that the coal is discharged from the mill 4 when the mill is normally stopped. The coal output simulation signal 21 predicted to be output is output to the switch 39, and the switch output 39 outputs the coal output simulation signal 21 as the coal output 23.
[0012]
As a result, when one mill 4 is normally stopped, the remaining plural mills 4 enter the furnace 8 of the boiler 7 by the amount of coal output 23 expected to be discharged from the mill 4. The coal output 23 of the supplied coal is reduced.
[0013]
[Problems to be solved by the invention]
As described above, when coal is discharged from the mill 4 in order to normally stop the mill 4, the output amount 23 continues to be substantially constant for a predetermined time after the coal gate 9 is closed, and subsequently decreases. However, as described above, simply providing the first-order lag device 22 and generating the coal output simulation signal 21 sets the slope of the decrease in the coal output 23 only with a uniquely determined curve. since this is not possible, the actual coal output error between increases, it can not be said to be sufficient when viewed in accuracy, the lowered exhaust gas O ₂ is still fuel-excess steam temperature increases risk There was room for improvement.
[0014]
In view of such a situation, the present invention can accurately calculate the coal output 23 predicted to be output from the mill 4 when the mill is normally stopped. It is an object of the present invention to provide a device for calculating the amount of coal output at the time of normal stoppage of a coal fired boiler that eliminates the supply to the furnace 8 and prevents the exhaust gas O ₂ from decreasing and the steam temperature from rising.
[0015]
[Means for Solving the Problems]
In the present invention, the coal supply amount 11 input from the coal feeder 3 to the mill 4 is output as it is as a signal 11 'during steady operation , while it is output from the signal generator 37 when the coal gate 9 is closed during normal mill stop. A switch 36 for outputting a signal 38 of “0” as a signal 11 ′;
During steady operation, the signal 11 ′ output from the switch 36 is output as it is as the signal 12. On the other hand, when the coal gate 9 is closed at the time of normal mill stop, immediately before “0” is output from the switch 36 at that time. A switch 13 for holding a signal 11 ′ of the amount of coal supply 11 and outputting it as a signal 12 representing the amount of remaining coal;
During steady operation, a “0” signal 26 output from the signal generator 25 is output as a signal 30, while a “1” signal 28 output from the signal generator 27 when the coal gate 9 is closed during normal mill stoppage. A switch 29 for outputting as a signal 30;
When the signal 30 output from the switch 29 changes from “0” to “1”, the change is performed so that the rate of change is limited to a range below the set value and the rate of change correction signal 32 is output. Rate limiter 31;
A function generator 33 that calculates and outputs a coal output simulation gain 34 based on the change rate correction signal 32 output from the change rate limiter 31;
A coal output simulation gain 34 output from the function generator 33 is multiplied by the signal 12 of the coal supply amount 11 output from the switch 13, and the output expected to be output from the mill 4 when the mill is normally stopped. A multiplier 35 for outputting a coal quantity simulation signal 21;
A “0” signal 41 output from the signal generator 40 during normal operation is output as a signal 21 ′, while a coal output simulation signal 21 output from the multiplier 35 when the coal gate 9 is closed during normal mill stoppage. As a signal 21 ′,
An adder 24 for adding a signal output 23 from a signal 21 'output from the switch 36 to a signal 11' output from the switch 36;
The present invention relates to a coal output calculation device when a coal fired boiler is normally stopped .
[0016]
[0017]
According to the above means, the following operation can be obtained.
[0018]
[0019]
In the coal output calculation device at the time of normal stop of the coal fired boiler of the present invention, the coal supply amount 11 input from the coal feeder 3 to the mill 4 during normal operation is indicated as a signal 11 ′ via the switch 36. While being output to the adder 24, the signal 11 ′ of the coal supply amount 11 passes through the switch 13 and is directly output to the multiplier 35 as the signal 12, but “0” output from the signal generator 40. Is output from the switch 42 to the adder 24 as a signal 21 ', so that the coal supply amount 11 is output as it is as the coal output 23 from the adder 24, while the mill 4 is normally stopped. When the coal gate 9 of the coal bunker 1 corresponding to the mill 4 is closed, the switch 36 outputs a signal 38 of “0” output from the signal generator 37 as a signal 11 ′. Signal 11 'is coal gate 9 Although it becomes “0” at the time of chaining, the changer 13 is a signal 11 ′ of the coal supply amount 11 immediately before becoming “0” output from the changer 36 at the time when the coal gate 9 is closed at the time of normal mill stop. And is output to the multiplier 35 as a signal 12 representing the amount of remaining coal. When the coal gate 9 is closed, a signal 28 of “1” output from the signal generator 27 is supplied from the switch 29 to the signal 30. Is output to the rate-of-change limiter 31, and the rate-of-change limiter 31 limits the rate of change of the signal 30 from the switch 29 that has changed from "0" to "1" within a range equal to or less than the set value. The change rate correction signal 32 is output to the function generator 33, and the function generator 33 obtains the coal output simulation gain 34 based on the change rate correction signal 32 output from the change rate limiter 31. Output to multiplier 35 In the multiplier 35, the coal output simulation gain 34 output from the function generator 33 is multiplied by the signal 12 of the coal supply amount 11 output from the switch 13, and the coal output from the mill 4 is output when the mill is normally stopped. The coal output simulation signal 21 predicted to be output is output as a signal 21 ′ to the adder 24 through the switch 42, and the adder 24 outputs a signal 21 ′ ( The coal output simulation signal 21) output from the multiplier 35 is added to the signal 11 ′ output from the switch 36 (which is “0” after the coal gate 9 is closed). Is output.
[0020]
As a result, when one mill 4 is normally stopped, the remaining plural mills 4 enter the furnace 8 of the boiler 7 by the amount of coal output 23 expected to be discharged from the mill 4. The coal output 23 of the supplied coal is reduced.
[0021]
Here, as in the prior art, simply providing the primary delay device 22 and generating the coal output simulation signal 21 produces the coal output when coal is output from the mill 4 in order to normally stop the mill 4. In the case of the present invention, the combination of the change rate limiter 31 and the function generator 33 can be used to set the slope of decrease in the coal output 23, Since it can be set as a function of time corresponding to the test data in the actual machine, the error between the coal output amount 23 output from the adder 24 and the actual coal output amount is minimized, and the fuel is excessive. Thus, the exhaust gas O ₂ does not decrease and the steam temperature does not increase.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0023]
1 and 2 show an example of an embodiment of the present invention. In the figure, the same reference numerals as those in FIGS. 3 to 5 denote the same components, and 29 is a signal generator during steady operation. 25, the signal 26 output from the signal generator 25 is output as the signal 30, while the signal gate 27 is output as the signal 30 when the coal gate 9 is closed when the mill is normally stopped. When the signal 30 output from the switching device 29 changes from “0” to “1”, the changer 31 controls the change rate within a range equal to or less than the set value to change the change rate correction signal 32. Is a function generator that calculates and outputs a coal output simulation gain 34 based on a change rate correction signal 32 output from the change rate limiter 31, and 35 is from the function generator 33. Simulated gay output 34 is a multiplier that outputs a coal output simulation signal 21 that is predicted to be output from the mill 4 when the mill is normally stopped. A signal 41 of “0” output from the signal generator 40 is sometimes output as a signal 21 ′, while a simulated coal output signal 21 output from the multiplier 35 is signaled when the coal gate 9 is closed when the mill is normally stopped. A switch 24 that outputs as 21 'is an adder 24 that adds a signal 21' output from the switch 42 to a signal 11 'output from the switch 36 and outputs a coal output 23.
[0024]
The change rate of the change rate limiter 31 and the function of the function generator 33 are set based on previously performed test data.
[0025]
Next, the operation of the illustrated example will be described.
[0026]
At the time of steady operation, the amount 11 supplied to the mill 4 from the coal feeder 3 is output to the adder 24 as a signal 11 ′ via the switch 36, and the signal 11 ′ of the amount 11 is switched. Although the signal 12 is output as it is to the multiplier 35 via the unit 13, the “0” signal 41 output from the signal generator 40 is output from the switch 42 to the adder 24 as the signal 21 ′. From the adder 24, the coal supply amount 11 is output as the coal output amount 23 as it is.
[0027]
On the other hand, when the coal gate 9 of the coal bunker 1 corresponding to the mill 4 is closed in order to normally stop the mill 4, the switch 36 outputs the “0” signal 38 output from the signal generator 37 to the signal 11. As shown in FIG. 2, the coal supply signal 11 ′ changes from “x [ton / h] to“ 0 ”when the coal gate 9 is closed. When the gate 9 is closed, the signal 11 ′ of the coal supply amount 11 immediately before “0” output from the switch 36 is held and output to the multiplier 35 as a signal 12 representing the remaining coal amount.
[0028]
When the coal gate 9 is closed, a signal 28 of “1” output from the signal generator 27 is output as a signal 30 from the switch 29 to the change rate limiter 31. A process of limiting the rate of change of the signal 30 from the switch 29 that has changed from “0” to “1” within a range below the set value is performed, and a rate of change correction signal 32 is output to the function generator 33, Based on the change rate correction signal 32 output from the change rate limiter 31 in the generator 33, a coal output simulation gain 34 is obtained and output to the multiplier 35, and in the multiplier 35, from the function generator 33. The output coal output simulation gain 34 is multiplied by the signal 12 of the coal supply amount 11 output from the switch 13, and the output coal simulation signal 21 predicted to be output from the mill 4 when the mill is normally stopped. Switch 42 Then, the signal is output to the adder 24 as a signal 21 ′. In the adder 24, the signal 21 ′ output from the switch 42 (the simulated coal output signal 21 output from the multiplier 35) is the switch. 36 is added to the signal 11 ′ (which is “0” after the coal gate 9 is closed), and is output as the coal output 23.
[0029]
As a result, when one mill 4 is normally stopped, the remaining plural mills 4 enter the furnace 8 of the boiler 7 by the amount of coal output 23 expected to be discharged from the mill 4. The coal output 23 of the supplied coal is reduced.
[0030]
Here, as in the prior art, simply providing the primary delay device 22 and generating the coal output simulation signal 21 produces the coal output when coal is output from the mill 4 in order to normally stop the mill 4. 23, the slope of decrease can only be set with a curve that is uniquely determined, but in the case of this illustrated example, the combination of the change rate limiter 31 and the function generator 33 can reduce the slope of decrease in the coal output 23. Since it can be set as a function of time corresponding to the test data in the actual machine, the error between the coal output 23 output from the adder 24 and the actual coal output is minimized, and the fuel Excess gas does not decrease the exhaust gas O ₂ or increase the steam temperature.
[0031]
In this way, the coal output 23 predicted to be output from the mill 4 at the time of normal stop of the mill can be obtained with high accuracy, and more than necessary coal exceeding the fuel flow rate command is supplied into the furnace 8 of the boiler 7. This can prevent the exhaust gas O ₂ from decreasing and the steam temperature from rising.
[0032]
It should be noted that the coal output calculating device at the time of normal stoppage of the coal fired boiler of the present invention is not limited to the above illustrated example, and various modifications can be made without departing from the scope of the present invention. Of course.
[0033]
【The invention's effect】
As described above, according to the coal output calculation device at the time of normal mill stop of the coal fired boiler according to the present invention, the coal output 23 predicted to be output from the mill 4 at the time of normal mill stop is obtained with high accuracy. it can, excessive coal above the fuel flow rate command eliminated that would be supplied to the furnace 8 of the boiler 7, an excellent effect of being able to prevent deterioration and increase of the steam temperature of the exhaust gas O ₂ .
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating an example of an embodiment of the present invention.
FIG. 2 is a time chart illustrating an example of an embodiment of the present invention.
FIG. 3 is a schematic diagram showing a coal supply system of a general coal fired boiler.
FIG. 4 is a block diagram illustrating an example of a coal output calculation device when a conventional coal fired boiler is normally stopped in a mill.
FIG. 5 is a time chart diagram of the conventional example shown in FIG. 4;
[Explanation of symbols]
3 coal feeder 4 mil 11 coal feed amount 12 signal 13 selector 21 coal output simulation signal 21 'signal 23 coal output 24 adder 25 signal generator 26 signal 27 signal generator 28 signal 29 selector 30 signal 31 change Rate limiter 32 Change rate correction signal 33 Function generator 34 Carburizing amount simulation gain 35 Multiplier 36 Switch 37 Signal generator 38 Signal 40 Signal generator 41 Signal 42 Switch

Claims (1)

During steady operation, the coal supply amount (11) input from the coal feeder (3) to the mill (4) is directly output as a signal (11 '), while a signal is generated when the coal gate (9) is closed during normal mill stoppage. A switch (36) for outputting a signal (38) of "0" output from the device (37) as a signal (11 ');
During steady operation, the signal (11 ′) output from the switch (36) is output as it is as the signal (12), while when the coal gate (9) is closed during normal mill stop, the switch (36) is at that time. A switch (13) that holds the signal (11 ′) of the coal supply amount (11) immediately before becoming “0” and is output as a signal (12) representing the remaining coal amount;
The signal (26) of “0” output from the signal generator (25) at the time of steady operation is output as the signal (30), while the coal gate (9) is closed at the time of normal mill stop from the signal generator (27). A switch (29) for outputting the output signal (28) as a signal (30);
When the signal (30) output from the switch (29) changes from "0" to "1", a process for limiting the change rate to a range equal to or less than a set value is performed to change the change rate correction signal ( 32) output rate limiter (31),
A function generator (33) for obtaining and outputting a coal output simulation gain (34) based on the change rate correction signal (32) output from the change rate limiter (31);
The coal output simulation gain (34) output from the function generator (33) is multiplied by the signal (12) of the coal supply amount (11) output from the switch (13), and the mill ( A multiplier (35) for outputting a coal output simulation signal (21) predicted to be output from 4);
The signal (41) of “0” output from the signal generator (40) during steady operation is output as a signal (21 ′), while the multiplier (35) when the coal gate (9) is closed during normal mill stop. A switcher (42) for outputting the coal output simulation signal (21) output from as a signal (21 ');
An adder (24) for adding a signal (21 ') output from the switch (42) to a signal (11') output from the switch (36) and outputting a coal output (23); An apparatus for calculating a coal output when a coal fired boiler is normally stopped.

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