JP3512556B2 - Dust concentration measurement device - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention collects flue gas from a boiler or a waste incinerator of a thermal power plant,
The present invention relates to a dust concentration measuring device that measures the concentration of soot and dust contained therein.

[0002]

BACKGROUND OF THE INVENTION Flue gas discharged from such a boiler, other dust, such as dust, NO _X, SO _X, because it contains air pollutants, such as hydrogen chloride, air pollution prevention Therefore, it is necessary to measure the emission amount of the boiler and the like with a dust concentration meter and a gas component analyzer in terms of operation management. As a dust densitometer for such a purpose, a light transmissive densitometer for measuring the amount of transmitted light of the irradiation light of the flue gas and a light transmissive densitometer for measuring the amount of scattered light are widely used. Also, as a gas component analyzer, N
O _X infrared spectrometer using a difference in absorption characteristics of the infrared analysis by component like is widely used.

In any of these devices, a sampling tube is inserted into the flue and a sample gas is collected by a suction pump or the gas flow pressure in the flue. Further, in the case of the gas component analyzer, dust such as dust interferes with the analysis operation, so that the dust filter using a heat-resistant filter material such as glass wool is removed before the analyzer. Furthermore, if water vapor in the sample gas condenses in the sampling probe or in each device, dust, N
O _X, SO _X, and the like atmospheric pollutants, such as hydrogen chloride is absorbed into the condensation water, because the measurement error is caused to occur, the heating device or kept in the portion where the temperature of the sample gas are likely to be lowered Measures have been taken to prevent dew condensation by using wood so that the temperature does not drop below the dew point.

Since the sampling tubes required for the dust concentration meter and the gas component analyzer are separately installed in the flue gas corresponding to the separately provided meters, the installation cost is high. In addition, there is a problem that the installation location must be selected so as not to interfere with each other. Therefore, as a solution to this problem, a sampling probe described in JP-A-6-66691 has been proposed. As shown in FIG. 3, the sample gas collected from inside the flue 1 is guided to the measurement chamber 11 of the dust densitometer outside the flue, and the gas after the dust concentration measurement is filtered by the filter 12
The structure of a sampling probe 14 is disclosed, which is filtered by a filter and is led to a gas component analyzer 13. The probe 14 is covered with an insulating sleeve, and the measuring chamber 11 and the filter 12 are also disclosed.
Is housed in a heat insulating case to prevent dew condensation.

Since such a structure is adopted, it is possible to measure and analyze the dust concentration and gas components from the flue gas collected by one probe, the installation work cost is halved, and the installation site is compact. Although the effects of getting rid of restrictions were obtained, the following new problems arose.

First, when the filter is replaced or the gas component analyzer is maintained and inspected, the suction of the sample gas is stopped, but at the same time, the dust concentration meter must be stopped. Secondly, the dust densitometer is equipped with an air curtain to prevent overheating of the optical system in contact with the sample gas and to prevent contamination by dust, but the air supplied to this air curtain leaks to the system of the component analyzer. And cause an error in the component analyzer.

Thirdly, as shown in the embodiment of the invention described in the above publication, in the case where the filter portion is connected to the large diameter soot concentration measuring chamber, the sample gas flows from the fine diameter probe to the measuring chamber. There is a possibility that accurate measurement may be hindered by a sudden increase in the inner diameter of the gas flow channel when flowing into the chamber, a pressure loss of the filter, or the like, which causes a flow velocity decrease and the dust settles down due to gravity.

[0008]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and the sampling tubes of the dust concentration analyzer and the gas component analyzer do not interfere with each other, and the respective instruments are not interfered with each other. The present invention provides a dust concentration measuring device that can operate independently and is less likely to cause a decrease in flow velocity in the flow path of the sample gas.

[0009]

[Problems to be Solved by the Invention] The above problem is that the sample gas collected from the flue gas is passed through the measurement chamber, while light is emitted from the light source and the scattered light or transmitted light is measured to determine the dust concentration. A dust concentration measuring device equipped with a dust concentration meter that can be calculated and calculated, and a gas component sampling pipe that can be connected to a gas component analyzer through a dust filter. Sampling tube that forms a gas inlet that can be placed at a depth of the flue and that is folded back outside the flue and that has the other end that forms a gas outlet that can be placed in the flue at a position that creates a differential pressure with the gas inlet. And a measurement chamber of the dust densitometer is formed in a portion outside the flue, and a portion of the gas component sampling pipe including a gas intake port inserted into the flue Provided in parallel close to the dust sampling tube, and with these dust sampling tube
On the same mounting plate as the gas component sampling pipe
It is fixed and can be attached to the flue casing.
This can be solved by a dust concentration measuring device characterized in that

Further, the above-mentioned problem is calculated by irradiating light from a light source while passing sample gas collected from a flue gas through a measuring chamber and measuring scattered light or transmitted light to calculate a dust concentration. A dust concentration measuring device that is equipped with a dust concentration meter that can be connected to a gas component analyzer through a dust filter, and has one end at a predetermined depth in the flue. A dust sampling tube that forms a gas inlet that can be arranged and that is folded back outside the flue and that forms at the other end a gas outlet that can be arranged in the flue at a position that creates a differential pressure with said gas inlet, A measurement chamber of the dust concentration meter is formed outside the flue, and the gas component sampling pipe is installed outside the flue in a large amount on the inlet side of the measurement chamber.
It is connected to the dust sampling tube through which the gas, more
This can also be solved by a dust concentration measuring device characterized in that a small amount of sample gas for gas component analysis is arranged so that it can be collected.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Next, a first embodiment of the present invention will be described with reference to FIG. In the dust concentration measuring apparatus of this embodiment, a gas component sampling pipe 2 for collecting a sample gas for gas component analysis from the flue 1 and a dust sampling pipe 3 for collecting a sample gas for dust concentration measurement are provided. It is annexed. The dust sampling tube 3 has a flue 1 in the first half 32 thereof.
Is formed at a predetermined depth inside and forms a gas inlet 31 which is obliquely opened in the upstream direction at a position where it receives the total fluid pressure of the flue gas, and the other is formed after being drawn out of the flue. , U-turn, and the final end of the latter half portion 34 forms a gas outlet 33 that is obliquely opened in the downstream direction inside the flue, and the measurement chamber 35 of the dust concentration meter is provided outside the flue. Are formed.

In this case, since there is a pressure difference between the gas intake port 31 and the gas discharge port 33 based on the gas flow according to the insertion depth in the flue 1, depending on the pressure difference, about 50 liters per minute is obtained. The arrangement position, the inner diameter of the pipe, the flow path resistance, etc. are set so that the gas in the flue flows in from the gas intake port 31 and flows out from the gas discharge port 33. In this way, the sample gas passing through the measurement chamber 35 provided outside the flue of the dust sampling tube 3 is irradiated with light from the light source, and scattered light or transmitted light is measured to measure the dust concentration. Is configured to measure.

Further, the gas component sampling pipe 2 provided along with this dust concentration measuring device is connected to a gas component analyzer (not shown) via a dust filter 25 having heat resistance such as inorganic wool and a suction pump 4. It consists of a possible latter half 24 and a first half 22 for taking in the sample gas, of which the part containing the gas intake 21 inserted into the flue approaches the flue inner part of the dust sampling tube. And are provided in parallel. Here, the dust sampling pipe 3 and the gas component sampling pipe 2 are fixed to a mounting plate 5 and attached to a flue casing.

Next, a second embodiment of the present invention will be described with reference to FIG. In this embodiment, the form relating to the dust sampling tube 3 is not different from that of the first embodiment described above, but the gas component sampling tube 2 has the measurement chamber 35 of the dust concentration meter at the tip of the front half portion 22 thereof. Is connected to the portion outside the flue of the dust sampling pipe 32 immediately before, and the other end reaches the latter half 24 through the filter 21 made of a heat-resistant filter material such as inorganic wool, and the gas component analyzer through the suction pump 4. 5 (not shown). With such a configuration, by operating the suction pump 4, the sample gas for gas component analysis is sucked and collected at about 3 liters per minute regardless of the sample gas to the dust concentration meter, and the filter gas is collected. After removing the dust at 21, the gas can be supplied to the gas component analyzer 5.

In the first and second embodiments described above, the amount of gas flowing through the dust sampling tube 3 is
It is appropriately determined by the pressure difference of the fluid pressure in the flue 1 at the gas inlet 31 and the gas outlet 33 and the flow path resistance in the probe, and it is proportional to the gas flow velocity in the flue 21. There is an advantage that the sample gas increases as the gas flow velocity in the flue increases.

Further, in the first embodiment, the flow of the sample gas in the gas component analyzer system and the flow of the sample gas in the dust concentration meter system are independent from each other and are not affected by each other. Since there is no interference, the installation location can be freely selected, which has the advantage of reducing the installation work cost.

Further, in the second embodiment, by arranging only the dust sampling pipe 3 in the flue, there is an advantage that the sample gas can be supplied to both the dust concentration meter and the gas component analyzer. In addition, the sample gas is separated by the gas component sampling pipe 2 which is branched outside the flue, but the amount required for gas component analysis should be as small as about 1/15 of the gas amount required for dust concentration measurement. Therefore, the flow of the sample gas in the dust concentration meter system is not affected by the flow of the sample gas in the gas component analyzer system, and the sample gas in the gas component analyzer system is due to the suction pump. , Not affected by the flow of sample gas in the dust concentration meter system.

Further, in any of the above embodiments, the measurement chamber 3 of the dust densitometer provided in the dust sampling tube 3 is provided.
Since the inner diameters of the probe 5 and the probe 3 before and after the same are formed to be the same inner diameter of 20 mm, there is no place where the inner diameter changes abruptly in the flow path, so that the flow velocity of the sample gas decreases as in the conventional example described above. In addition to the above, there is no fear of being affected by the sample gas of the gas component analysis system as described above, so that there is an advantage that it can be measured as a stable gas.

Further, the sample gas collected from the flue gas will vary depending on the composition, but if it is maintained at 140 ° C. or higher, no dew condensation will occur even under considerably bad conditions. Therefore, in the present invention, since the dust sampling tube 3 and the gas component sampling tube 2 are arranged close to each other, it can be easily embodied such as winding a sheath heater to heat and keep the temperature.

[0020]

Since the dust concentration measuring device of the present invention is constructed as described above, the air curtain air leaking from the dust concentration meter operates in addition to the above-described effects. In addition, since there is no sudden expansion of the gas flow passage inner diameter or pressure loss of the filter, there is no decrease in flow rate, dust does not settle down by gravity, and there is an effect that there is no obstacle to dust concentration measurement. Second
Also in the case of the embodiment, there is an excellent effect that the operation of the dust concentration meter is not affected if the gas component sampling pipe inlet is closed at the time of replacement of the filter or maintenance and inspection of the gas component analyzer. Therefore, the present invention has an extremely great industrial value as a dust concentration measuring device which solves the conventional problems.

[Brief description of drawings]

FIG. 1 is a sectional view of an essential part for explaining a first embodiment of the present invention.

FIG. 2 is a sectional view of an essential part for explaining a second embodiment of the present invention.

FIG. 3 is a sectional view of a main part showing a conventional example.

[Explanation of symbols]

1 flue, 2 gas component sampling pipe, 21 gas intake, 25 filter, 3 dust sampling pipe, 3
1 gas inlet, 32 gas outlet, 35 measuring chamber, 4
Suction pump, 5 gas component analyzer.

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A 61-247939 (JP, A) JP-A 8-75621 (JP, A) JP-A 8-68734 (JP, A) JP-A 6- 66691 (JP, A) Actually open 62-28154 (JP, U) Actually open 60-114948 (JP, U) Actually open 6-78846 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) G01N 1/00-1/44 G01N 15/00-15/14 JISST file (JOIS)

Claims (2)

(57) [Claims] 1. Dust that is irradiated with light from a light source while passing sample gas collected from a flue gas through a measurement chamber and measures scattered light or transmitted light to calculate a dust concentration for calculation. A dust concentration measuring device having a densitometer and a gas component sampling pipe that can be connected to a gas component analyzer through a dust filter,
A gas outlet, one end of which forms a gas intake that can be arranged at a predetermined depth in the flue and which is folded back outside the flue and the other end of which can be arranged in a position in the flue where a differential pressure is provided with the gas intake. Equipped with a dust sampling tube to form
A measurement chamber of the dust concentration meter is formed in the portion outside the flue, and among the gas component sampling tubes,
A portion including a gas inlet inserted into the flue is provided in parallel with and close to the dust sampling tube , and
Part of dust sampling tube and gas component sampling tube
Fixed to a common mounting plate and attached to the flue casing.
A dust concentration measuring device characterized in that it can be attached . 2. A dust which is irradiated with light from a light source while passing a sample gas taken from a flue gas through a measuring chamber and measuring scattered light or transmitted light to calculate a dust concentration for calculation. A dust concentration measuring device having a densitometer and a gas component sampling pipe that can be connected to a gas component analyzer through a dust filter,
A gas outlet, one end of which forms a gas intake that can be arranged at a predetermined depth in the flue and which is folded back outside the flue and the other end of which can be arranged in a position in the flue where a differential pressure is provided with the gas intake. Equipped with a dust sampling tube to form
A measurement chamber of the dust densitometer is formed outside the flue, and the gas component sampling pipe is connected to the dust sampling pipe on the inlet side of the measurement chamber where a large amount of gas flows outside the flue. , Smaller gas component analysis
A dust concentration measuring device, characterized in that it is arranged so as to be able to collect the sample gas for use .