JPH10239237A - Method and device for duct concentration measurement - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for correcting a zero point that can be automated easily in a dust concentration meter and to prevent a measurement error from occurring by extremely suppressing the drift of the zero point. SOLUTION: Air nozzles 14a and 14b are provided at each of the side of a gas intake port 11 and the side of a gas discharge port 12 of a sampling pipe 1 with the gas intake port 11 at one edge and the gas discharge port 12 at the other edge while the discharge port of air nozzles 14a and 14b is directed toward a gas intake port 11 and the gas discharge port 12, and automatic air valves 15a and 15b that are switched by the signal of a controller 31 for controlling a zero point calibration operation are provided at these. Also, while the air nozzles 14a and 14b are pinched, a dust concentration meter body is located at the sampling pipe 1, and a dust concentration operator 30 for calculating a concentration indication value from a dust concentration sensor output is provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method for collecting flue gas from a boiler or a waste incinerator of a thermal power plant,
The present invention relates to a dust concentration measuring method for measuring the concentration of dust contained therein and an improvement of the measuring device.

[0002]

2. Description of the Related Art Measuring the concentration of dust and other dust contained in flue gas discharged from boilers, incinerators, etc. is necessary in the operation management of boilers and the like in order to prevent air pollution. Has become. As a dust concentration measuring device for such a purpose, a light transmission type measuring device that irradiates flue gas with light and measures the amount of transmitted light, or a light scattering type measuring device that measures the amount of scattering and reflection. Is widespread.

[0003] The measurement of the dust concentration by such a dust concentration measuring device will be described with reference to FIG. The sampling pipe 1 penetrates the flue wall 10 and is located inside the flue (FIG.
The gas inlet 11 is disposed on the left side of the flue wall 10) and the U-turn is made outside the flue (right side in FIG. 5) via the manual valve 13 and the dust concentration meter main body 2 to communicate with the inside of the flue. An outlet 12 is provided. In this case, the measurement gas is taken in from the gas inlet 11 due to the flow pressure difference of the gas in the flue, and is measured in the measurement chamber 21 of the dust concentration meter main body 2.
And finally reflux from the gas outlet 12 into the flue.

On the other hand, in the measurement room 21, the light source 2
3 irradiates the measurement gas with light, measures the amount of transmission or scattering of the gas with a sensor provided in the light receiver 22, and outputs the obtained sensor output to the dust concentration calculator 30 to display the concentration value on the indicator. The dust concentration measuring device is configured to perform the measurement. In this way, the dust concentration of the gas in the flue can be measured continuously.

The principle of measuring the dust concentration in this case will be described for the light scattering method. First, clean air is selected as a reference body having a dust concentration of 0, and the sensor output when the clean air is introduced into the measurement chamber is set to Szero, and the display of the concentration value of the indicator at that time (hereinafter, referred to as an indication value) is set to 0. I do. Next, Sspan is the sensor output when a reference body (hereinafter, referred to as SPAN) whose dust density value is equivalent to Mspan, and the horizontal axis is the sensor output and the vertical axis is the indicated value, as shown in FIG. Create a calibration curve. If the sensor output obtained for the measurement gas whose concentration is unknown is S, the concentration can be obtained as the indicated value X based on the calibration curve. The dust concentration calculator 30 performs a numerical operation based on the relationship between the sensor output and the indicated value, and has a function of displaying the indicated concentration value or a function of transmitting a signal therefor.

In the dust concentration meter which operates as described above, the dust concentration is set to 0 before the actual measurement.
In this case, the sensor output Szero is measured in advance, and the measurement is performed by setting the density instruction value in this case (this value is generally referred to as a zero point because this value is based on 0).
The zero point deviates from 0 due to a change in the scattering rate over time due to dust adhesion in the measurement chamber, or an electrical or mechanical change in the indicator over time, and stops shifting to some extent (drift). I can't get it. If such a drift of the zero point occurs, an error naturally occurs in the measured density. Therefore, the sensor output Szero in the case of dust density = 0 is measured again, and the newly obtained sensor output Szero is obtained.
An operation of resetting the indicated value to 0 with 1zero is required. Such an operation of correctly resetting the relationship between the sensor output and the indicated value is called zero point calibration.

By the way, in the dust concentration measuring device illustrated in FIG. 5 as described above, the zero point calibration as described above is performed according to the following procedure. 1) The manual valve 13 provided in the flow path on the side of the measurement gas inlet 11 is closed to stop the flow of the measurement gas. 2) To prevent contamination of the optical system lens and the like in the measurement chamber 21,
The measuring chamber is set to a clean air atmosphere by the supplied clean purge air. Excess air is discharged from the discharge port 12 into the flue. 3) Next, after the indicated value of the dust concentration calculator 30 is stabilized, the setting of the dust concentration calculator 30 is manually changed so that the indicated value becomes 0, and zero point calibration is performed.

The method for calibrating the zero point of such a dust concentration measuring apparatus has the following disadvantages. 1) Each time the zero-point calibration operation is performed, it is necessary to operate the manual valve provided in the vicinity of a flue such as a combustion furnace or a dust removal device, a bag filter, or the like. Despite this, it was troublesome to go to a distant site.

2) In recent years, in order to reduce harmful substances such as dioxin in combustion exhaust gas, high-performance bag filters have been adopted for dust collectors, and the dust concentration to be managed is about several mg / m ³ . Since the density has become low, it is important to ensure the accuracy of the dust concentration, especially the accuracy near the zero point.

However, when the operation of the combustion furnace or the like is started or stopped, a bypass operation is usually performed around the bag filter to protect the filter. In such a bypass operation, the exhaust gas enters a dust concentration measuring device in a dust concentration state of a high concentration of g / m ³ unit level, so that the contamination in the measurement chamber is accelerated. During the steady operation after the end of the bypass operation, there is a problem that the error in the dust concentration measurement in the low concentration region becomes large.

3) An attempt was made to increase the number of times the zero-point calibration was performed to cope with the above-mentioned problem. However, during the zero-point calibration operation, the manual valve was closed and the flow of the measurement gas was stopped. Therefore, dust will be deposited between the gas inlet and the manual valve, and when the measurement is restarted, this deposited dust will flow into the measuring chamber in a short time, contaminating the inside and drifting the zero point, There was also an inconvenience that daily maintenance work increased.

[0012]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems. First, it is an object of the present invention to provide a zero-point calibration method which can easily automate a dust concentration measuring apparatus. The present invention provides a dust concentration measuring method and a dust concentration measuring device which can suppress a zero point drift as much as possible and prevent a measurement error from occurring even if the dust concentration of a measurement gas fluctuates greatly during the bypass operation as described above.

[0013]

The above problem can be solved by a dust concentration measuring method described below. (1) The gas to be measured is taken in from the gas inlet located in the flue, guided to the outside of the flue, and the dust concentration is measured by a dust concentration meter via an on-off valve, and then the gas outlet arranged in the flue. In the method for measuring the concentration of dust emitted from the apparatus, while the on-off valve is closed and the measurement chamber of the dust concentration meter is filled with clean air, the output S1zero of the dust concentration sensor is measured, and the indicated value of the concentration meter at that time is measured. This is a method of performing a zero-point calibration operation for calibrating as 0 at appropriate intervals, and after each zero-point calibration operation, opening the on-off valve and measuring the dust concentration sensor output S with the measurement gas taken in. A dust concentration X obtained by the following formula (A) or (B). (A) X = (S−S1zero) × (M−Z) / (Sspan−S1zero) (B) X = (S−S1zero) × M / (Sspan−S0zero)

Here, Sspan is a sensor output value when a calibration reference (SPAN) corresponding to a predetermined dust concentration is set in the measurement room, and a fixed value is used until the next SPAN is performed. M is a predetermined dust concentration value specific to the calibration reference (SPAN). S0zero is the dust density sensor output at the time of the previous zero calibration. Z is
This is a densitometer indication value immediately before the current zero calibration, indicated by the dust concentration sensor output S1zero in a state where the measurement chamber is filled with clean air. The meanings of these symbols are the same hereinafter.

(2) Similar to the above (1), in the dust concentration measuring method for measuring the dust concentration in the measurement gas, the dust concentration sensor output S1zero is similarly measured, and the zero point calibration operation is performed at appropriate intervals. A dust concentration measuring method comprising: measuring a dust concentration sensor output S after each zero point calibration operation; and obtaining a dust concentration X by the following formula. X = (S−S1zero) M / (Sspan−S1zero)

(3) Similar to the above (1), in the dust concentration measuring method for measuring the dust concentration in the measurement gas, the dust concentration sensor output S1zero is similarly measured, and the zero point calibration operation is performed at appropriate intervals. A dust concentration measuring method comprising: measuring a dust concentration sensor output S after each zero point calibration operation; and obtaining a dust concentration X by the following formula. X = (S−S1zero) M / (Sspan × A−S1zero) where A is S1zero / S0zero or S1zero−S
The coefficient is determined by 0zero.

(4) The gas inlet side of the sampling tube having a gas inlet for taking in the gas to be measured in the flue at one end and a gas outlet for discharging the gas to be measured into the flue at the other end. And means for discharging high-pressure air in the flue direction on each of the gas discharge ports, and the pressurized air discharge means includes a pressurized air valve which is opened and closed by a signal of a zero point calibration control means, and Dust concentration measurement, characterized in that a measurement chamber for a concentration meter with a dust concentration sensor is provided in the middle of the pressurized air discharging means, and a dust concentration calculator is provided for calculating a concentration indication value from the output of the dust concentration sensor. apparatus.

(5) A measuring gas is taken in from a gas inlet arranged in the flue, guided to a dust concentration measuring chamber outside the flue, and measured for the dust concentration, and then discharged from a gas outlet arranged in the flue. In the dust concentration measuring method, the dust concentration sensor output S1zero is measured in a state where the dust concentration measuring chamber is filled with clean air, and the relationship between the sensor output and the indicated value is calibrated by setting the indicated value of the densitometer at that time to 0. A method of performing a zero point calibration operation at appropriate intervals, wherein each of the zero point calibration operations is performed by pressurized air discharging means provided between the gas inlet and the gas discharge port and the dust concentration measurement chamber. After performing the test while discharging the pressurized air in the respective directions of the gas inlet and the gas outlet, the output S of the dust concentration sensor is measured with the measurement gas taken in, and the following is performed. The calculation formula of A) or (B), the dust concentration measuring method and obtains the dust concentration X. (A) X = (S−S1zero) × (M−Z) / (Sspan−S1zero) (B) X = (S−S1zero) × M / (Sspan−S0zero) where Sspan, M and Z are as defined above. As defined above.

(6) The dust concentration measuring method according to the above (5), wherein Z = 0 is replaced in equation (A) or S0zero = S1zero in equation (B) Dust concentration measurement method to find. (7) The dust concentration measuring method according to (5), wherein Sspan is a ratio of S1zero / S0zero or a difference S1zero.
-A dust concentration measuring method for obtaining a dust concentration X by multiplying by a coefficient A determined by S0zero.

[0020]

Next, an embodiment of the present invention will be described with reference to FIGS. (1) First, in the dust concentration measuring method of the present invention, a dust concentration measuring method for measuring the dust concentration of a measurement gas while repeatedly performing zero point calibration at appropriate intervals after the previous zero point calibration and SPAN point calibration. As the dust concentration measuring device, the one exemplified in FIG. 5 described above can be used. That is, the measurement gas is taken in from the gas inlet 11 arranged in the flue, guided to the outside of the flue, and is opened and closed.
After measuring the dust concentration in the measurement chamber 21 of the dust concentration meter main body 2 via the gas outlet 3, the gas discharge port 12 arranged in the flue is
In the method for measuring the concentration of dust emitted from the apparatus, the on-off valve 2 is closed and the dust concentration sensor output S1zer
is measured and the concentration measurement device indication value at that time is set to 0, and calibration is performed. This zero-point calibration operation is repeated at appropriate intervals.

After the zero point calibration operation, when the on-off valve 13 is opened and the dust concentration is measured with the measurement gas taken in, the characteristic of the dust concentration measuring method of the present invention is that the sensor output S is The dust concentration X is determined by the measurement and the following equation (A) or (B). (A) X = (S−S1zero) × (M−Z) / (Sspan−S1zero) (B) X = (S−S1zero) × M / (Sspan−S0zero)

In this case, Sspan is a sensor output value when a calibration reference (SPAN) corresponding to a predetermined dust concentration is set in the measurement room, and a fixed value is used until the next SPAN is performed. M is a predetermined dust concentration value unique to the calibration reference (SPAN).
S0zero is the dust density sensor output at the time of the previous zero calibration. Further, Z is a densitometer indication value immediately before the current zero calibration indicated by the dust concentration sensor output S1zero in a state where the measurement chamber is filled with clean air. The meanings of these symbols are the same hereinafter.

The above equations (A) and (B) show substantially the same relationship, and will be described with reference to the graph of FIG. 1 in which the horizontal axis represents the sensor output and the vertical axis represents the instrument indicated value. . The calibration curve when the sensor output S0zero at the previous zero point calibration and the sensor output Sspan at the SPAN point calibration is K
Set to 0. Then, after a certain period of time, when the sensor output when the zero point calibration is performed again is S1zero,
Assuming that a new calibration curve is translated from the previous calibration curve K0, it can be obtained as a calibration curve K1.

In this case, the following relationship is established between the sensor output and the indicated value, so that equation (A) is obtained. X / (M−Z) = (S−S1zero) / (Sspan−S1zer)
o) At the same time, the following relationship is also satisfied, so that equation (B) is also obtained. X / M = (S-S1zero) / (Sspan-S0zero)

Therefore, if the sensor output S1zero obtained by the new zero-point calibration is applied to the above equation (A) or (B) to calculate, the dust concentration containing an error due to the drift of the zero point is calculated. The indicated value can be corrected assuming that the calibration curve has moved in parallel by the difference between the previous sensor output S0zero at the time of zero point calibration and the current sensor output S1zero. The concentration indication value obtained in this way is
Since it also includes the drift of the sensor output at the SPAN point,
Even if the frequency of SPAN point calibration is less than the frequency of zero point calibration, there is an advantage that practical accuracy can be maintained. further,
By using the previous sensor output S0zero and the current sensor output S1zero at the time of zero point calibration, the calibrated concentration indication value can be obtained by a simple calculation formula, so that there is an advantage that the zero point calibration can be easily automated. can get.

(2) Next, a second embodiment will be described. Similar to the above (1), the dust concentration for measuring the dust concentration in the measurement gas while performing the zero point calibration operation at appropriate intervals. In the measurement method, the dust concentration sensor output S
Is measured, and a dust concentration X is obtained by the following formula. X = (S−S1zero) M / (Sspan−S1zero)

The sensor output S0zero at the time of the previous zero point calibration and the sensor output Sspan at the time of the SPAN point calibration will be further described with reference to the graph of FIG. Calibration curve K
Set to 0. Then, after a certain period of time, when the sensor output when the zero point calibration is performed again is S1zero,
Assuming that only the zero point has moved from the previous calibration curve K0, a new calibration curve can be obtained as a calibration curve K1. Then, in this case, since the sensor output and the support value have the following relationship, the above formula is obtained. X / M = (S-S1zero) / (Sspan-S1zero)

Therefore, if the sensor output S1zero obtained by the new zero-point calibration is applied to the above-described formula and calculated, the dust concentration indication value including the time-dependent error can be replaced with the previous sensor output S0zero at the time of the zero-point calibration. And this time sensor output S1z
It can be corrected by the calibration curve with the zero point shifted by the difference from ero. Therefore, there is an advantage that practical accuracy can be maintained even if the frequency of the SPAN point calibration is less than the frequency of the zero point calibration. Further, in this method, the concentration indication value calibrated by a simple calculation formula can be obtained only by using the latest sensor output S1zero at the time of the zero point calibration, so that the zero point calibration can be easily automated. The possible benefits are obtained.

(3) Further, a third embodiment will be described. In this embodiment, the dust concentration X is obtained by the following equation instead of the equations used in the first and second cases. This is a characteristic method for measuring dust concentration. X = (S−S1zero) M / (Sspan × A−S1zero) where A is S1zero / S0zero or S1zero−S
This coefficient is determined by 0zero, and is selected to a value in the range of 0.8 to 1.5.

Here, a further explanation will be given with reference to the graph of FIG. 3 in which the horizontal axis indicates the sensor output and the vertical axis indicates the instrument indicated value. The sensor output S0zero at the time of the previous zero point calibration and the sensor output Sspan at the time of the SPAN point calibration will be described. Calibration curve K
Set to 0. Then, after a certain period of time, when the sensor output when the zero point calibration is performed again is S1zero,
Span × A obtained by correcting the sensor output at the SPAN point by the coefficient A
Is prepared in correspondence with the indicated value M. Then, in this case, since the sensor output and the indicated value have the following relationship, the above formula is obtained. X / M = (S−S1zero) / (Sspan × A−S1zero)

In the example of FIG. 3, the case where A <1 is shown, but the change with time is caused by the structure of the optical system of the dust densitometer and the degree of contamination thereof, or the characteristics of the electric circuit of the sensor device. Since the slope of the calibration curve is not always uniform, a characteristic change may occur in each instrument. Therefore, if the characteristics of each device are known in advance, and the coefficient A is set as a variable of S1zero so that the gradient of the calibration curve is scheduled so as to match the characteristics, the frequency of the SPAN point calibration can be reduced. Thus, the measurement accuracy can be kept high.

According to this embodiment, if the sensor output S1zero obtained by the new zero-point calibration is applied to the above-described formula and calculated, the dust concentration indication value containing an error due to the zero point drifting is obtained. Can be corrected by a calibration curve calibrated according to the characteristics of the equipment used. In addition to maintaining high measurement accuracy, a simple calculation formula can be obtained simply by using the latest sensor output S1zero at the time of zero point calibration. Thus, the concentration indication value calibrated by the above can be obtained, so that there is an advantage that the zero point calibration can be easily automated similarly to the previous embodiment.

(4) Next, an embodiment of the dust concentration measuring apparatus of the present invention will be described with reference to FIG. In this embodiment, a sampling pipe 1 provided with a gas inlet 11 for taking in a measurement gas in a flue at one end, and a gas outlet 12 for discharging a measurement gas into the flue at the other end.
A dust concentration meter main body 2 is disposed in the middle of the sensor, a measurement gas is introduced into a concentration measurement chamber 21, a light source 23 irradiates the measurement gas with light, and a light transmission amount or a scattering amount is provided by a light receiver 22. The obtained sensor output is transmitted to the dust concentration calculator 30 and is formed so as to display the density value on the indicator in the same manner as described above.

The feature of the present invention is that each of the gas inlet side and the gas outlet side of the sampling tube 1 has
As means for discharging the high-pressure air in the flue direction, air nozzles 14a and 14b are provided with the discharge ports facing the gas inlet 11 and the gas discharge port 12, respectively. Further, high-pressure air is supplied to the air nozzles 14a and 14b from a high-pressure air tank (not shown) or the like, and the air nozzles 14a and 14b are opened and closed by a signal from a controller 31 for controlling a zero-point calibration operation. Automatic air valve 15
a and 15b are provided. The dust concentration meter main body 2 is located in the sampling tube 1 in such a manner that the air nozzles 14a and 14b are sandwiched between the air nozzles 14a and 14b, and the concentration indication value is obtained from the sensor output corresponding to the dust concentration of the sensor provided in the light receiver 22. A dust concentration calculator 30 for calculating is provided.

According to the dust concentration measuring apparatus of this embodiment, pressurized air can be discharged from the air nozzles 14a and 14b toward the gas inlet 11 and the gas discharge port 12 for zero point calibration. Even if the dust concentration of the measurement gas fluctuates greatly during operation, it is possible to effectively prevent the dust from flowing into the sampling pipe. Is obtained.

(5) Next, an embodiment of the dust concentration measuring method including the operation of discharging the pressurized air as described above will be described. In this case, the operation of intake and release of the measurement gas and the output of the dust concentration sensor S1zero for the clean air are performed.
Is performed, and the zero point calibration operation is performed at appropriate intervals as described above. The feature of this embodiment is that each zero point calibration operation is performed by the gas inlet and the gas outlet and the dust concentration. An air nozzle 14a provided between the air chamber and the measurement chamber;
14b, the pressurized air is discharged in the respective directions of the gas inlet 11 and the gas outlet 12, and then the output S of the dust concentration sensor is measured with the measurement gas taken in, and the following (A) Alternatively, a dust concentration measuring method is characterized in that the dust concentration X is obtained by the formula (B). (A) X = (S−S1zero) × (M−Z) / (Sspan−S1zero) (B) X = (S−S1zero) × M / (Sspan−S0zero) where Sspan, M and Z are as defined above. As defined above.

According to this embodiment, even if the dust concentration of the measurement gas fluctuates greatly during the bypass operation, it is possible to effectively prevent dust from flowing into the sampling pipe. To the advantage,
As in the previous embodiment (1), even if the frequency of the SPAN point calibration is less than the frequency of the zero point calibration, practical accuracy can be maintained and the previous sensor output S0zero at the time of the zero point calibration.
By using the sensor output S1zero and this time, the calibrated concentration indication value can be obtained by a simple calculation formula, so that the advantage that the zero point calibration can be easily automated can be obtained.

Further, as an embodiment (6), in the dust concentration measuring method described in the above (5), Z = 0 may be replaced in the equation (A) as in the previous embodiment (2), or ( It can be embodied as a dust density measuring method for obtaining the dust density X by replacing S0zero = S1zero in the equation B). Further, the embodiment (7)
In the dust concentration measurement method described in (5), Sspan and S1zero /
The present invention can be embodied in a dust concentration measuring method for obtaining the dust concentration X by multiplying the coefficient A determined by the S0zero ratio or the difference S1zero-S0zero. And in these embodiments, the advantage described in the above (5) and
The present invention can be implemented as having the advantages described in the respective embodiments (2) and (3). The above description is based on the light scattering type dust densitometer, but the same can be applied to the light transmission type.

[0039]

Since the dust concentration measuring method and apparatus of the present invention are configured as described above, it is possible to easily automate the measuring method including the zero point calibration method. Even if the dust concentration of the measurement gas fluctuates greatly during the bypass operation, dust intrusion can be prevented, or the invaded dust can be positively discharged, so that drift of the zero point can be suppressed as much as possible and measurement errors can be prevented. In addition, there is an excellent effect that daily maintenance work can be reduced. Therefore, the present invention has an extremely large industrial value as a dust concentration measuring method and an apparatus for solving the conventional problems.

[Brief description of the drawings]

FIG. 1 is a graph showing a relationship between a sensor output and a concentration instruction value for explaining an embodiment of the present invention.

FIG. 2 is a graph showing a relationship between a sensor output and a concentration instruction value for explaining a second embodiment.

FIG. 3 is a graph illustrating a relationship between a sensor output and a concentration instruction value for explaining a third embodiment;

FIG. 4 is a model diagram showing a flow of a measurement gas of the dust concentration meter of the present invention.

FIG. 5 is a model diagram showing a flow of a measurement gas of the dust concentration meter.

FIG. 6 is a graph showing a relationship between a sensor output and a concentration instruction value.

[Explanation of symbols]

Reference Signs List 1 sampling pipe, 11 gas inlet, 12 gas outlet, 14a, 14b air nozzle, 15a, 15b automatic air valve, 2 dust concentration meter main body, 21 concentration measurement chamber,
23 light source, 22 light receiver, 30 dust concentration calculator,
31 Zero point calibration operation controller.

Claims (7)

[Claims] 1. A measuring gas is taken in from a gas inlet disposed in a flue, guided out of the flue, measured for dust concentration by a dust concentration meter via an on-off valve, and then placed in the flue. In the method for measuring the concentration of dust discharged from a discharge port, the on-off valve is closed, and the output of the dust concentration sensor S is measured in a state where the measurement chamber of the dust concentration meter is filled with clean air.
(1) A method in which zero is measured, and a zero point calibration operation for calibrating the concentration meter indication value at that time as 0 is provided at appropriate intervals, and after each zero point calibration operation, the open / close valve is opened and measurement is performed. A dust concentration measuring method characterized in that a dust concentration sensor output S is measured in a state where gas is taken in, and a dust concentration X is obtained by the following formula (A) or (B). (A) X = (S−S1zero) × (M−Z) / (Sspan−S1zero) (B) X = (S−S1zero) × M / (Sspan−S0zero) where Sspan is a predetermined dust concentration. The sensor output value when the corresponding calibration reference (SPAN) is set in the measurement room, and a fixed value is used until the next SPAN is performed. M is a predetermined dust concentration value specific to the calibration reference (SPAN). S0zero is the dust density sensor output at the time of the previous zero calibration. Z is a densitometer indication value immediately before the current zero calibration indicated by the dust concentration sensor output S1zero in a state where the measurement chamber is filled with clean air. 2. A measuring gas is taken in from a gas inlet arranged in the flue, guided to the outside of the flue, and measured for dust concentration by a dust concentration meter via an on-off valve, and then placed in the flue. In the method for measuring the concentration of dust discharged from a discharge port, the on-off valve is closed, and the output of the dust concentration sensor S is measured in a state where the measurement chamber of the dust concentration meter is filled with clean air.
(1) A method in which zero is measured, and a zero point calibration operation for calibrating the concentration meter indication value at that time as 0 is provided at appropriate intervals, and after each zero point calibration operation, the open / close valve is opened and measurement is performed. A dust concentration measuring method, wherein a dust concentration sensor output S is measured in a state where gas is taken in, and a dust concentration X is obtained by the following formula. X = (S−S1zero) M / (Sspan−S1zero) where Sspan is a sensor output value when a calibration reference (SPAN) corresponding to a predetermined dust concentration is set in the measurement room, and the next SPAN is calculated. Until this is done, use a fixed value. M is a predetermined dust concentration value specific to the calibration reference (SPAN). 3. A measuring gas is taken in from a gas inlet disposed in the flue, guided to the outside of the flue, and the dust concentration is measured by a dust concentration meter via an on-off valve. In the method for measuring the concentration of dust discharged from the discharge port, the output of the dust concentration sensor S1zero is measured in a state where the on-off valve is closed and the measuring chamber of the dust concentration measuring device is filled with clean air. In this method, a zero point calibration operation for calibrating an indicated value as 0 is provided at appropriate intervals, and after each zero point calibration operation, the on-off valve is opened, and the dust concentration sensor output S And measuring the dust density X by the following formula. X = (S−S1zero) M / (Sspan × A−S1zero) where Sspan is a sensor output value when a calibration reference (SPAN) corresponding to a predetermined dust concentration is set in the measurement chamber, and is the latest value. Shows the measured values. M is a predetermined dust concentration value specific to the calibration reference (SPAN). A
Is a coefficient determined by S1zero / S0zero or S1zero-S0zero. Here, S0zero is the sensor output at the time of the previous zero point calibration. 4. A sampling tube having a gas inlet at one end for taking in a measurement gas in a flue and a gas outlet at the other end for discharging a measurement gas into the flue; Each of the gas discharge ports is provided with a means for discharging high-pressure air in the flue direction, and the pressurized air discharge means is provided with a pressurized air valve which is opened and closed by a signal from a zero point calibration control means. A dust concentration meter having a dust concentration sensor provided in the middle of the compressed air discharging means, and a dust concentration calculator for calculating a concentration indication value from the output of the dust concentration sensor; apparatus. 5. Dust released from a gas outlet disposed in a flue after measuring gas is taken in from a gas inlet disposed in the flue and led to a dust concentration measuring chamber outside the flue to measure the dust concentration. In the density measuring method, the dust density sensor output S1zero is measured in a state where the dust density measuring chamber is filled with clean air, and the relationship between the sensor output and the indicated value is calibrated by setting the indicated value of the density measuring device at that time to 0. A method of automatically performing a zero-point calibration operation at appropriate intervals, wherein each of the zero-point calibration operations is performed by a pressurized air provided between the gas inlet and the gas outlet and the dust concentration measurement chamber. After performing the discharge while discharging the pressurized air in the respective directions of the gas inlet and the gas discharge port, the output S of the dust concentration sensor is measured with the measurement gas taken in. A dust concentration X obtained by the following formula (A) or (B). (A) X = (S−S1zero) × (M−Z) / (Sspan−S1zero) (B) X = (S−S1zero) × M / (Sspan−S0zero) where Sspan is a predetermined dust concentration. The sensor output value when the corresponding calibration reference (SPAN) is set in the measurement room, and a fixed value is used until the next SPAN is performed. M is a predetermined dust concentration value specific to the calibration reference (SPAN). S0zero is the dust density sensor output at the time of the previous zero calibration. Z is a densitometer indication value immediately before the current zero calibration indicated by the dust concentration sensor output S1zero in a state where the measurement chamber is filled with clean air. 6. The dust density measuring method according to claim 5, wherein Z = 0 is replaced in the equation (A) or S0zero = S1zero in the equation (B) to obtain the dust density X. Concentration measurement method. 7. The dust concentration measuring method according to claim 6, wherein Sspan is a ratio of S1zero / S0zero or a difference S1zer.
o A dust concentration measuring method for obtaining a dust concentration X as a product of a coefficient A determined by -S0zero. Where S
0zero is the sensor output at the time of the previous zero point calibration.