JP2003130768A - Sulfur trioxide concentration measuring instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sulfur trioxide concentration measuring instrument which can continuously and easily measure the SO3 concentration in an exhaust gas. SOLUTION: This sulfur trioxide concentration measuring instrument includes a flow passage having an inlet section which guides the exhaust gas from a flue, a heater which heats the exhaust gas in the flow passage to a temperature higher than the dew point of sulfur trioxide, and a filter which removes solid matters from the exhaust gas. This instrument also includes a sucking means which guides the exhaust gas in the flue to the flow passage, a cooling chamber which transforms sulfur trioxide into mist by cooling the exhaust gas passing through the heater and filter to a temperature lower than the dew point of the sulfur trioxide, and an optical particle densitometer which measures the concentration of sulfur trioxide transformed into the mist in the exhaust gas in the cooling chamber. Sulfur trioxide can be transformed into mist by cooling the cooling chamber and diluting the sulfur trioxide by means of a separate dried-gas line connected to the sucking means. The inlet section of the flow passage can also be positioned on the downstream side of the exhaust gas flow in the flue. When a desulfurizing agent is supplied into the flue, an electrical precipitator can be used instead of the filter.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sulfur trioxide concentration measuring device for measuring the concentration of sulfur trioxide contained in exhaust gas, and particularly to a device for continuously measuring sulfur trioxide concentration in exhaust gas easily. The present invention relates to a sulfur oxide concentration measuring device.

[0002]

2. Description of the Related Art Sulfur trioxide (= sulfuric acid anhydride, hereinafter referred to as SO ₃
However, since SO ₃ reacts violently with water to form sulfuric acid and corrodes iron products such as flues, it is necessary to accurately grasp the amount of SO ₃ contained in exhaust gas.

FIG. 5 is a schematic view of a conventional sulfur trioxide concentration measuring device. Exhaust gas containing SO ₃ flows in the direction of arrow F in the flue 101. In the exhaust gas, gasified SO ₃ and mist SO ₃ are mixed. A sampling pipe 110 having a dust filter 111 installed at its tip is pushed in the exhaust gas passage 101 of the flue 101. The filter 111 serves to remove solids contained in the exhaust gas in the flue 101, for example, heavy oil combustion ash. The sampling tube 110 is fixed to the flue 101 by a support member 112. The sampling pipe 110 is provided with a heater 120 for warming the exhaust gas, a quartz spiral pipe 130 for capturing SO ₃ , a suction drain pump 140 for removing water, a suction pump 150, glass or polyfluoride. They are connected by a pipe 180 made of ethylene fiber. In the subsequent stage of the suction pump 150, a drain bottle 160 and a gas meter 170 are provided on the downstream side, and a pipe 180 made of glass or polyfluoroethylene fiber is also used.
Connected by. A thermometer 171 and a pressure gauge 172 are attached to the gas meter 170.

The spiral tube 130 is placed in a hot water bath 131, and the suction pump 150 is provided with a bypass 151. FIG. 6 is a detailed view of the spiral tube 130.
A grinding portion 132 is provided on the downstream side of the spiral tube 130, and the quartz wool 1 is provided in the grinding portion 132.
33 is filled.

Prior to the measurement of the SO ₃ amount, the heater 120
The sampling tube 110 to 200 degrees Celsius or above,
1, the spiral tube 130 is preheated to 90 degrees Celsius or higher. When the preheating is completed, the suction pump 150 is operated to suck a predetermined amount of exhaust gas, and SO ₃ is condensed and captured in the spiral tube 130. The amount of sucked exhaust gas is measured by the gas meter 170.

When the suction of a predetermined amount of gas is completed, the spiral tube 130 is removed and the inside of the spiral tube 130 is washed with pure water. For this cleaning liquid, for example, JIS
SO ₃ by precipitation titration method based on K0103
The amount can be quantified and the amount of exhaust gas measured by gas meter 170 can be used to determine the SO ₃ concentration in the exhaust gas.

[0007]

However, in such a prior art sulfur trioxide concentration measuring device, the S
It takes a certain time, for example, 20 to 30 minutes, to sample O ₃ in the spiral tube 130. Furthermore, since the chemical analysis is performed after cleaning the spiral tube 130, it takes a relatively long time to measure the SO ₃ concentration once. Therefore, it is impossible to continuously measure the SO ₃ concentration with the conventional sulfur trioxide concentration measuring device. Further, in order to improve the measurement accuracy, it is necessary to perform such sampling and chemical analysis a plurality of times, which further extends the entire measurement time.

Further, a certain degree of proficiency is required for the work of using the sulfur trioxide concentration measuring device of the prior art, for example, cleaning of the spiral tube 130 and chemical analysis, and a plurality of operators need to have SO ₃ concentration. When measuring, the data may vary.

[0009] At present, the flue 10 is sprayed with a desulfurizing agent, for example, an alkaline chemical such as baking soda particles.
There are systems designed to remove SO ₃ in 1. In the case of such a system, the desulfurizing agent in the exhaust gas is captured by the filter 111, and a layer made of the desulfurizing agent is formed in the filter. At least a part of SO ₃ or SO ₂ in the exhaust gas is formed by the layer composed of the desulfurizing agent,
It can be removed before being captured by the spiral tube 130. Therefore, it is difficult to accurately and continuously measure the concentration of SO ₃ contained in the exhaust gas in the flue 101.

Therefore, the present invention can continuously and easily measure the SO ₃ concentration in the exhaust gas, and continuously and accurately measure the concentration of sulfur trioxide even in the case of the system in which the desulfurizing agent is sprayed into the flue. It is an object of the present invention to provide a sulfur trioxide concentration measuring device that can be used.

[0011]

In order to achieve the above-mentioned object, according to the invention as set forth in claim 1, there is provided a flow path having an inlet portion for guiding the exhaust gas from the flue, and the inside of the flow path. A heater for heating the exhaust gas to a temperature higher than the dew point of sulfur trioxide, a filter for removing solids in the exhaust gas, and a suction for guiding the exhaust gas in the flue to the flow path. Means, a cooling chamber for cooling the exhaust gas that has passed through the heater and the filter to a temperature lower than the dew point of sulfur trioxide to mist sulfur trioxide,
Provided is a sulfur trioxide concentration measuring device including an optical particle densitometer for measuring the concentration of mistified sulfur trioxide in exhaust gas in the cooling chamber. That is, according to the invention of claim 1, the SO
_{The 3} concentrations can be measured continuously and easily.

According to the second aspect of the present invention, a flow path having an inlet for guiding the exhaust gas from the flue and the exhaust gas in the flow path are heated to a temperature higher than the dew point of sulfur trioxide. A heater for heating, a filter for removing solids in the exhaust gas, a suction means for guiding the exhaust gas in the flue to the flow path, the exhaust gas that has passed through the heater and the filter A cooling chamber for cooling and diluting sulfur trioxide to a temperature lower than the dew point of sulfur trioxide by a dry gas in a separate dry gas line to mist sulfur trioxide, and mist sulfur trioxide in exhaust gas in the cooling chamber An optical particle densitometer for measuring the concentration of sulfur trioxide is provided. That is, according to the invention described in claim 2, SO ₃ in the exhaust gas can be relatively easily cooled by the additional dry gas, for example, dry air. In addition, the exhaust gas can be diluted to make it suitable for measurement by an optical particle densitometer.

According to the third aspect of the present invention, the inlet portion of the flow passage located in the flue is located downstream of the exhaust gas flow in the flue. That is, according to the third aspect of the present invention, the solid content in the exhaust gas, such as heavy oil combustion ash, is less likely to enter the inlet of the flow path, so that the filter of the sulfur trioxide concentration measuring device is prevented from being clogged. Therefore, the frequency of filter replacement can be reduced.

According to the fourth aspect of the present invention, it further includes a return passage for returning the exhaust gas in the cooling chamber to the flue. That is, according to the invention described in claim 4, it is possible to prevent an operator in the vicinity of the sulfur trioxide concentration measuring device from sucking SO ₃ in the exhaust gas.

According to the fifth aspect of the present invention, a flow path having an inlet for guiding the exhaust gas from the flue and the exhaust gas in the flow path are heated to a temperature higher than the dew point of sulfur trioxide. A heater for heating, an electric dust collector for removing solids in the exhaust gas, a suction means for guiding the exhaust gas in the flue to the flow path, the exhaust gas passing through the heater and the filter A cooling chamber for cooling and diluting sulfur trioxide with a dry gas in a separate dry gas line to a temperature lower than the dew point of sulfur trioxide to mist sulfur trioxide, and misted trioxide in exhaust gas in the cooling chamber. An apparatus for measuring sulfur trioxide concentration is provided that includes an optical particle densitometer for measuring the concentration of sulfur. That is, according to the invention described in claim 5, even in the case of a system for removing SO ₃ by supplying a desulfurizing agent, for example, baking soda to the flue, the SO ₃ concentration in the exhaust gas can be accurately and continuously measured. .

According to the sixth aspect of the present invention, the inlet portion of the flow passage located in the flue is located downstream of the flow of the exhaust gas in the flue. That is, according to the invention as set forth in claim 6, even when the desulfurizing agent is sprayed on the exhaust gas in the flue gas, the solid content in the exhaust gas, for example, heavy oil combustion ash, is less likely to enter the inlet portion of the flow path. Therefore, the frequency of cleaning the electric dust collector of the sulfur trioxide concentration measuring device can be reduced.

According to the seventh aspect of the present invention, it further includes a return passage for returning the exhaust gas in the cooling chamber to the flue. That is, according to the invention described in claim 7, it is possible to prevent an operator in the vicinity of the sulfur trioxide concentration measuring device from sucking SO ₃ in the exhaust gas.

According to the invention described in claim 8, an additional flow path for guiding the exhaust gas from the flue, an additional heater for heating the exhaust gas in the additional flow path, and the additional heater An additional filter for removing solids in the exhaust gas in the flow channel and a spiral tube provided downstream of the additional heater and the additional filter with respect to the flow of the exhaust gas in the flow channel are further provided. And the spiral tube is located in a hot bath. That is, according to the invention described in claim 8, it is possible to easily perform the calibration operation for SO ₃ in the flue before using the continuous sulfur trioxide concentration measuring apparatus of the present invention.

According to the ninth aspect of the invention, a spiral pipe provided in a branch flow path branched from the downstream of the filter is further included, and the spiral pipe is arranged in the high temperature tank. That is, according to the invention as set forth in claim 9, calibration of SO _{3 in} a flue is performed before using the continuous sulfur trioxide concentration measuring apparatus of the present invention without requiring an additional heater, an additional filter and the like. The action can be easily performed.

[0020]

DETAILED DESCRIPTION OF THE INVENTION Embodiments of the present invention will be described below with reference to the accompanying drawings. In the following drawings, the same members are designated by the same reference numerals. FIG. 1 is a schematic diagram of a sulfur trioxide concentration measuring apparatus according to the first embodiment of the present invention. In FIG. 1, a sampling pipe 20 extending from the exhaust gas passage in the flue 11 is provided as in the above-described conventional technique. The inlet portion 21 of the sampling pipe 20 faces upstream with respect to the flow of exhaust gas in the exhaust gas passage in the flue 11. As can be seen from FIG. 1, a heater 31 is arranged around the sampling tube 20. The sampling tube 20 is the support member 1
It is fixed to the flue by 12. The filter 3 is provided downstream of the heater 31 with respect to the flow of the exhaust gas in the sampling pipe 20.
2 are arranged. Further, a flow meter 33 is provided downstream of the filter 32. In order to suck the exhaust gas from the flue 11 into the sampling pipe 20, a suction means, for example, an ejector or a pump 34 is arranged downstream of the flow meter 33. A cooling chamber or a dilution chamber 35 is provided downstream of the suction means 34. The flow path 25 extending from the dilution chamber 35 returns to the inside of the flue 11.

As shown in FIG. 1, the sulfur trioxide concentration measuring apparatus of the present invention includes a dry gas line. In the dry gas line, a dry gas, for example compressed air, is supplied by a pump 41 from a dry gas source (not shown) to a suction means 34 through a valve 43 and a flow meter 44. Further, the pipe 61 extending from the dilution chamber 35 communicates with the optical particle concentration measuring device 63, and then the pipe 62 extending from the optical particle concentration measuring device 63 is connected to the dilution chamber 3.
It communicates with the flow path 25 for returning the exhaust gas in 5 to the flue 11. The data measured by the optical particle concentration measuring device, for example, the digital dust meter 63 is calculated by the arithmetic device, for example, the computer 64, and then output by the output device, for example, the monitor or the printer 65.

During operation, the exhaust gas in the flue 11 is introduced into the sampling tube 20 through the inlet portion 21 by the suction means 34. As described above, most of the SO in the flue 11
₃ is gasified but part of SO ₃ is misted, and gasified SO ₃ and misted SO ₃ are mixed. The exhaust gas flowing into the sampling pipe 20 is heated by the heater 31 when passing through the heater 31. Heater 31 is S
The temperature is set to a temperature higher than the acid dew point of O ₃ , for example, about 200 ° C., and when the exhaust gas passes through the sampling pipe in the heater 31, all of the SO ₃ contained in this exhaust gas is gasified.

Next, the exhaust gas in which all SO ₃ is gasified passes through the filter 32. This removes solids in the exhaust gas, such as heavy oil combustion ash or unburned carbon. Then, the exhaust gas from which the solid content has been removed flows into the diluting chamber 35 through the orifice or flow meter 33 and the suction means 34. As described above, the dry gas from the dry gas source (not shown), for example, dry air, is supplied to the valve 43,
It passes through the flow meter 44 and the suction means 34 and simultaneously flows into the dilution chamber 35.

In the diluting chamber 35, the exhaust gas is diluted with the dry gas. As a result, the exhaust gas is diluted by the optical particle concentration measuring device 63 to a concentration suitable for measuring the SO ₃ concentration. Since the dry gas used in the present invention is at room temperature, the exhaust gas is also cooled by this dry gas. This dry gas causes the temperature of the exhaust gas in the dilution chamber 35 to be lower than the acid dew point of SO ₃ , for example, 40 ° C. As a result, all of SO ₃ in the exhaust gas becomes mist in the dilution chamber 35. That is, all SO ₃ in the exhaust gas has a diameter of 0.1 μm to 0.1 μm.
The particles are about 3 micrometers.

Next, such mist-ized SO ₃
The exhaust gas containing the is supplied from the dilution chamber 35 to the optical particle concentration measuring device 63 through the pipe 61, and the SO ₃ concentration in the exhaust gas is continuously monitored in the optical particle concentration measuring device 63. Then, the computing device 64 causes the SO
₃ Concentration is calculated. Finally, the output device 65 outputs the SO ₃ concentration result. In the arithmetic unit 64, a separate S
S obtained in advance by an O ₃ concentration measuring means, for example, an SO ₃ concentration measuring means including a spiral tube used in the prior art.
The SO ₃ concentration is calculated using the calibration relational expression between the O ₃ concentration and the value indicated by the optical particle concentration measuring device 63.
FIG. 4 is a diagram showing a calibration test result. In FIG. 4, simulated exhaust gas is used, the horizontal axis is the value indicated by the optical particle concentration measuring device (digital dust meter) 63, and the vertical axis is SO.
₃ concentrations (measured values). As is clear from FIG. 4, since the SO ₃ concentration is proportional to the indicated value of the digital dust meter, it can be seen that the SO ₃ concentration can be measured by the sulfur trioxide concentration measuring device of the present invention.

In the present invention, as shown in FIG. 1, the exhaust gas in the dilution chamber 35 and the optical particle concentration measuring device 6
The exhaust gas measured in 3 is returned to the flue 11 again through the flow path 25. This can prevent the operator of the sulfur trioxide concentration measuring apparatus of the present invention from inhaling SO ₃ in the exhaust gas. In FIG. 1, the outlet of the flow path 25 for returning the exhaust gas into the flue 11 is located upstream of the flow of the exhaust gas in the flue 11, but this outlet is located at the inlet 21 of the sampling pipe 20. It is preferable that the SO ₃ concentration be downstream, and the SO ₃ concentration can be measured more accurately and continuously.

FIG. 2 is a schematic diagram of a sulfur trioxide concentration measuring apparatus according to the second embodiment of the present invention. In this embodiment, the sampling pipe 2 for sampling the exhaust gas in the flue 11
The inlet 21 of 0 is located downstream of the flow F of the exhaust gas in the flue 11. As described above, the exhaust gas in the flue 11 contains solids, for example, heavy oil combustion ash, but in the present embodiment, the solids in the exhaust gas are sucked into the inlet portion 21 due to inertial force. Without it, it will flow downstream of the inlet 21. Therefore, since the solid content captured by the filter 32 can be reduced, clogging of the filter 32 can be reduced and the frequency of filter replacement can be reduced. Incidentally, there is no need to consider the mist-diameter of SO ₃ is 0.3 micrometers 0.1 micrometers inertia contained in the exhaust gas in the flue 11, SO ₃ was mist inlet portion 21 is sucked.

FIG. 3 is a schematic diagram of a sulfur trioxide concentration measuring device according to a third embodiment of the present invention. The sulfur trioxide concentration measuring device according to the present embodiment has a desulfurizing agent,
For example, it is used in the case of a system in which an alkaline chemical such as baking soda particles is sprayed to remove SO ₃ in the flue. In the present embodiment, an electric dust collector 36 is arranged instead of the filter.

The exhaust gas in the flue 11 sucked from the inlet portion 21 of the sampling pipe 20 during operation flows into the electrostatic precipitator 36. The electrostatic precipitator included in the electrostatic precipitator 36 hardly captures SO ₃ because of its small contact area with the exhaust gas. Therefore, electrostatic Chirikyoku electrostatic precipitator 36, SO ₃
The solid content containing the desulfurizing agent is captured with almost no trapping. Since SO ₃ flows through the electrostatic precipitator to the dilution chamber, the SO ₃ concentration in the exhaust gas can be accurately and continuously measured even when the desulfurizing agent is sprayed in the flue.

In another embodiment of the present invention (not shown), the sulfur trioxide concentration measuring apparatus 10 uses an SO for obtaining in advance a calibration relational expression used for calculating the SO ₃ concentration in the arithmetic unit 64. ₃ Concentration measuring means is included. The SO ₃ concentration measuring means includes a hot water bath as shown in the above-mentioned prior art and a spiral tube contained in the hot water bath. That is, the SO ₃ concentration measuring means includes an additional flow path for guiding the exhaust gas from the flue, an additional heater arranged around the additional flow path for heating the exhaust gas, and an exhaust gas in the additional flow path. It includes an additional filter for removing the solid content, an additional heater, a spiral tube provided downstream of the additional filter, and a bath containing the spiral tube therein. The temperature of the hot water bath is 90 ° C or higher. By using such an SO ₃ concentration measuring means, a relational expression between the SO ₃ concentration acquired in advance and the indicated value of the optical particle concentration measuring device 63 is obtained, and the relational expression is used for the monitoring result. _{The 3} concentrations can be continuously determined. That is, it is possible to easily perform the calibration operation for SO ₃ in the flue before using the continuous sulfur trioxide concentration measuring apparatus of the present invention.

Further, such SO ₃ concentration measuring means may be provided with a flow path branched from the downstream side of the filter 32, a spiral pipe communicating with the flow path, and a hot water bath containing the spiral pipe therein. In this case, the calibration action for SO ₃ in the flue can be easily performed before using the continuous sulfur trioxide concentration measuring apparatus of the present invention without requiring an additional heater, an additional filter, and the like. be able to.

When the concentration of SO ₃ contained in the exhaust gas in the flue 11 is high, the dry gas is supplied to the dilution chamber 35 from the additional dry gas line including the valve 53 and the flow meter 54 as shown in FIG. By doing so, the exhaust gas in the diluting chamber 35 can be appropriately cooled and diluted. Further, in the above-described embodiment, the filter 32 is installed outside the flue 11 downstream of the heater 31 with respect to the flow of the exhaust gas in the sampling pipe 20 during operation. This allows the filter 32 to be easily replaced. As a matter of course, it is within the scope of the present invention to preliminarily remove the solid content and / or the water content in the dry gas by providing a filter and / or a hygroscopic agent in the supply channel for supplying the dry gas to the dilution chamber. .

[0033]

According to the invention described in each claim, there is a common effect that the SO ₃ concentration can be continuously and easily measured without the operator becoming proficient.

Further, according to the invention of claim 2,
SO ₃ in the exhaust gas is relatively easy due to the additional dry gas
Can be cooled and this exhaust gas can be diluted to make it suitable for measurement by an optical particle densitometer.

Further, according to the invention of claim 3,
Since the solid content in the exhaust gas is less likely to enter the inlet of the flow path, clogging of the filter of the sulfur trioxide concentration measuring device can be reduced, and the frequency of filter replacement can be reduced. The effect can be achieved.

Further, according to the invention of claim 4,
The operator near the sulfur trioxide concentration measuring device was
₃ can be prevented from being sucked. Furthermore, according to the invention described in claim 5, in the case of a system for removing SO ₃ by supplying desulfurizing agent into the flue can also be measured continuously accurately SO ₃ concentration in the exhaust gas The effect can be achieved.

Further, according to the invention of claim 6,
Even when desulfurizing agent is sprayed on the exhaust gas in the flue,
Since the solid content in the exhaust gas is less likely to enter the inlet of the flow path, it is possible to reduce the frequency of cleaning the electrostatic precipitator of the sulfur trioxide concentration measuring apparatus.

Further, according to the invention of claim 7,
The operator near the sulfur trioxide concentration measuring device was
₃ can be prevented from being sucked. Further, according to the invention described in claim 8, it is possible to obtain the effect that the calibration action for SO ₃ in the flue can be easily performed before using the continuous sulfur trioxide concentration measuring device of the present invention. .

Further, according to the invention of claim 9,
A calibration action for SO ₃ in the flue can be easily performed before using the continuous sulfur trioxide concentration measuring device of the present invention without the need for additional heaters, additional filters, etc. The effect can be achieved.

[Brief description of drawings]

FIG. 1 is a schematic diagram of a sulfur trioxide concentration measuring device according to a first embodiment of the present invention.

FIG. 2 is a schematic diagram of a sulfur trioxide concentration measuring device according to a second embodiment of the present invention.

FIG. 3 is a schematic diagram of a sulfur trioxide concentration measuring device according to a third embodiment of the present invention.

FIG. 4 is a diagram showing a calibration test result.

FIG. 5 is a schematic view of a conventional sulfur trioxide concentration measuring device.

FIG. 6 is a detailed view of a spiral tube.

[Explanation of symbols]

10 ... Sulfur trioxide concentration measuring device 11 ... Flue 20 ... Collection tube 21 ... Entrance 31 ... Heater 32 ... Filter 33 ... Flowmeter 34 ... Suction means 35 ... Dilution room 36 ... Electric dust collector 41 ... Pump 43 ... valve 44 ... Flowmeter 53 ... valve 54 ... Flowmeter 61 ... Piping 62 ... Piping 63 ... Optical particle concentration measuring device 64 ... Arithmetic device 65 ... Output device

   ─────────────────────────────────────────────────── ─── Continued front page    F term (reference) 2G052 AA02 AB08 AC25 AD02 AD22                       AD42 BA03 BA14 CA04 CA12                       DA09 EA03 EB13 FD01 FD18                       GA11 HA15 HC04 HC13 HC22                       HC28 HC40 JA04 JA09 JA24

Claims (9)

[Claims] 1. A flow path having an inlet for guiding exhaust gas from a flue, a heater for heating the exhaust gas in the flow path to a temperature higher than the dew point of sulfur trioxide, and the exhaust gas. A filter for removing the solid content inside, a suction means for guiding the exhaust gas in the flue to the flow path, the exhaust gas that has passed through the heater and the filter up to a temperature lower than the dew point of sulfur trioxide Sulfur trioxide concentration measuring device including a cooling chamber for cooling to mist sulfur trioxide, and an optical particle concentration meter for measuring the concentration of mistified sulfur trioxide in exhaust gas in the cooling chamber . 2. A flow path having an inlet for guiding exhaust gas from a flue, a heater for heating the exhaust gas in the flow path to a temperature higher than the dew point of sulfur trioxide, and the exhaust gas. A filter for removing the solid content inside, a suction means for guiding the exhaust gas in the flue to the flow path, the exhaust gas that has passed through the heater and the filter by a dry gas in a separate dry gas line A cooling chamber for cooling and diluting to a temperature lower than the dew point of sulfur trioxide to mist sulfur trioxide, and an optical system for measuring the concentration of mist sulfur trioxide in the exhaust gas in the cooling chamber. A sulfur trioxide concentration measuring device including a particle concentration meter. 3. The sulfur trioxide concentration measuring device according to claim 1, wherein the inlet portion of the flow path located in the flue is located downstream of the flow of exhaust gas in the flue. . 4. The sulfur trioxide concentration measuring device according to claim 1, further comprising a return flow path for returning the exhaust gas in the cooling chamber to the flue. 5. A flow path having an inlet for guiding exhaust gas from a flue, a heater for heating the exhaust gas in the flow path to a temperature higher than the dew point of sulfur trioxide, and the exhaust gas. An electrostatic precipitator for removing the solid content in the exhaust gas, a suction means for guiding the exhaust gas in the flue to the flow path, the exhaust gas having passed through the heater and the filter, a dry gas in a separate dry gas line A cooling chamber for cooling and diluting sulfur trioxide to a temperature lower than the dew point of sulfur trioxide to mist sulfur trioxide, and an optical device for measuring the concentration of mist sulfur trioxide in the exhaust gas in the cooling chamber. Sulfur trioxide concentration measuring device including a particle densitometer. 6. The sulfur trioxide concentration measuring device according to claim 5, wherein the inlet portion of the flow passage located in the flue is located downstream of the flow of the exhaust gas in the flue. 7. The sulfur trioxide concentration measuring device according to claim 5, further comprising a return flow path for returning the exhaust gas in the cooling chamber to the flue. 8. An additional flow path for guiding exhaust gas from the flue, an additional heater for heating the exhaust gas in the additional flow path, and a solid material in the exhaust gas in the additional flow path. And a spiral pipe provided downstream of the additional heater and the additional filter with respect to the flow of exhaust gas in the flow path, the spiral pipe being in a high temperature tank. 8. The sulfur trioxide concentration measuring device according to claim 1, wherein the sulfur trioxide concentration measuring device is arranged. 9. The spiral pipe according to claim 1, further comprising a spiral pipe provided in a branch flow passage branched from the downstream side of the filter, the spiral pipe being arranged in a high temperature bath. Sulfur trioxide concentration measuring device.