JP5147920B2 - Exhaust gas collection device and ammonia collection method using the same - Google Patents

Description

  The present invention relates to an exhaust gas collecting device for collecting a part of exhaust gas from an exhaust gas flow channel through which exhaust gas containing ammonia flows, and an ammonia collecting method using the same.

Conventionally, a denitration apparatus for denitrating nitrogen oxides (NO _x ) from exhaust gas from a boiler has been used. Such a denitration device mixes exhaust gas and ammonia gas by injecting ammonia gas into the exhaust gas, and reduces the mixture gas to nitrogen gas and water vapor by contacting the mixed gas with a denitration catalyst (for example, Patent Document 1). reference).

  In order to perform such injection of ammonia gas without excess or deficiency, for example, a part of the exhaust gas is collected in the exhaust gas passage on the outlet side of the denitration apparatus, and the ammonia amount (concentration) contained therein is accurately measured. There is a need. Therefore, an exhaust gas collection pipe (hereinafter referred to as a probe) is provided in the exhaust gas flow path, and a part of the exhaust gas is collected through this probe.

JP-A-5-163933

  However, when a part of the exhaust gas is collected through the probe, a small amount of ammonia adheres to the inside of the probe and remains. For this reason, it has been difficult to reliably extract ammonia contained in the exhaust gas, and it has been difficult to accurately measure the ammonia concentration.

  An object of the present invention is to provide an exhaust gas collecting device capable of reliably collecting ammonia contained in exhaust gas and an ammonia collecting method using the same.

The present invention is an exhaust gas collecting instrument that collects a part of the exhaust gas from an exhaust gas flow channel through which exhaust gas containing ammonia flows and introduces the exhaust gas into a collection device that collects ammonia contained in the exhaust gas. An opening for introducing the exhaust gas, a probe provided in the exhaust gas flow path, an opening for introducing the exhaust gas introduced into the probe on one end side, and configured in a tubular shape, and A flexible collection tube having one end side detachably inserted into the probe and the other end led out of the probe and connected to the collection device, the probe comprising: and operator includes a pair of metal rods example Bei a handle portion graspable extending in a direction intersecting the direction of extension of the probe, which detachably connected to the other end of the collection tube to the collection device The connecting member further includes a flexible coated tube covering the sampling tube led out from the probe, and a flexible tube provided on the probe, and one end of the coated tube being detachable from the probe. an exhaust gas sampling device Ru and a joint portion to be connected.

  Moreover, it is preferable that the said collection tube consists of a fluororesin.

  The present invention is an ammonia collection method for collecting a part of exhaust gas flowing through an exhaust gas flow path using an exhaust gas sampling device and collecting ammonia contained in a part of the exhaust gas. Collecting a part of the exhaust gas and introducing the exhaust gas part into the sampling device, and after the exhaust gas introduction process, removing one end of the sampling tube inserted into the probe from the probe A collection tube removing step, and washing water is injected from the opening of the collection tube removed from the probe by the collection tube removing step, and the ammonia adhering to the inside of the collection tube is collected together with the washing water and the collection device And a collection tube washing step to be introduced into the ammonia collection method.

  ADVANTAGE OF THE INVENTION According to this invention, the exhaust gas collection instrument which can extract | collect ammonia contained in waste gas reliably and the ammonia collection method using the same can be provided.

It is a mimetic diagram showing an ammonia collection system to which exhaust gas collection instrument 10 concerning an embodiment of the present invention is applied. It is a fragmentary sectional view showing exhaust gas sampling instrument 10 concerning an embodiment of the present invention.

  Hereinafter, an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a schematic diagram showing an ammonia collection system to which an exhaust gas collection device 10 according to an embodiment of the present invention is applied.

  The exhaust gas collecting device 10 according to the present embodiment is provided, for example, in an exhaust gas passage on the outlet side of a denitration device (not shown). As shown in FIG. 1, the exhaust gas collecting device 10 collects a part of the exhaust gas G from the exhaust gas passage 1 through which the exhaust gas G containing ammonia flows, and analyzes the amount of ammonia (ammonia concentration) contained in the exhaust gas G. Therefore, it is introduced into the collection device 100 for collection.

  First, an outline of the collection device 100 will be described with reference to FIG. The sampling device 100 is a device for carrying out the “method for analyzing ammonia in exhaust gas” defined in JISK0099. For example, the collection device 100 is configured to analyze (measure) the ammonia concentration by the indophenol method after absorption of ammonia gas by the absorption liquid.

  As shown in FIG. 1, the collection device 100 includes an introduction pipe 105, a first absorption bottle 120 and a second absorption bottle 125 containing an absorption liquid 110, a first connection pipe 127, an empty bottle 130, The main body includes a two-connection pipe 132, a pump 140, a third connection pipe 142, a gas meter 150, and a fourth connection pipe 152.

The introduction pipe 105 is a pipe that introduces the exhaust gas G derived from the exhaust gas collecting instrument 10 into the first absorption bottle 120. The absorbing liquid 110 is a boric acid solution having a predetermined concentration.
The first absorption bottle 120 and the second absorption bottle 125 are sealable glass bottles. Each of the first absorption bottle 120 and the second absorption bottle 125 contains a predetermined amount of absorption liquid 110.
The first connection pipe 127 connects the first absorption bottle 120 and the second absorption bottle 125. One end of the first connection pipe 127 is not immersed in the absorption liquid 110 in the first absorption bottle 120. The other end of the first connection pipe 127 is immersed in the absorbing liquid 110 in the second absorption bottle 125.

  The empty bottle 130 is an empty bottle that protects the pump 140 and the gas meter 150 from contamination due to the exhaust gas G, the absorbing liquid 110, and the like. The second connection pipe 132 connects the second absorption bottle 125 and the empty bottle 130. One end of the second connection pipe 132 is not immersed in the absorbing liquid 110 in the second absorption bottle 125. The other end of the second connection pipe 132 is connected to the empty bottle 130.

  The pump 140 sucks the exhaust gas G (sample gas), introduces it into the first absorption bottle 120, the second absorption bottle 125, and the empty bottle 130, and further sends it to the gas meter 150. The gas meter 150 measures the flow rate of the sucked exhaust gas G (sample gas). The third connection pipe 142 connects the empty bottle 130 and the pump 140. The fourth connection pipe 152 connects the pump 140 and the gas meter 150. In order to prevent dust in the exhaust gas G from entering the sampling device 100, predetermined filters (not shown) are provided at appropriate positions of the introduction pipe 105, the first connection pipe 127, and the second connection pipe 132. It is done.

Next, the exhaust gas collecting device 10 according to the embodiment of the present invention will be described in detail with reference to FIGS. 1 and 2. FIG. 2 is a partial cross-sectional view showing the exhaust gas collecting device 10 according to the embodiment of the present invention.
As shown in FIG. 1, the exhaust gas flow channel 1 is a pipe line constituted by a flow channel wall 2.
As shown in FIGS. 1 and 2, the exhaust gas collection device 10 includes a probe 12, a collection tube 20, and a connection member 30.

  As shown in FIGS. 1 and 2, the probe 12 is a metal member configured in a tubular shape. The probe 12 covers the collection tube 20 so that the collection tube 20 is not directly exposed to the high temperature exhaust gas G. The probe 12 is preferably made of, for example, stainless steel from the viewpoint of corrosion resistance.

  As shown in FIG. 2, the probe 12 includes an opening 13 (see FIG. 1), a large diameter portion 14, and a handle portion 15. As shown in FIG. 1, the opening 13 is provided on the one end 12 a side of the probe 12 and introduces a part of the exhaust gas G. As shown in FIG. 2, the large diameter portion 14 is provided on the other end 12 b side of the probe 12 and is configured to be thicker than the other portions of the probe 12.

As shown in FIG. 2, the handle portion 15 is provided in the large diameter portion 14. The handle portion 15 is a pair of metal bars extending in a direction intersecting with the direction in which the large diameter portion 14 extends, and can be gripped by an operator.
The probe 12 configured in this way is attached to the flow channel wall 2 with the opening 13 positioned in the exhaust gas flow channel 1.

  As shown in FIGS. 1 and 2, the collection tube 20 is a tube made of synthetic resin having both ends opened, and has flexibility. The collection tube 20 has an opening 21 (see FIG. 1) on one end 20a side and an opening 22 on the other end 20b side. The opening 21 introduces the exhaust gas G introduced into the probe 12. Further, the opening 22 discharges the exhaust gas G introduced into the collection tube 20 to the collection device 100. One end 20 a side of the collection tube 20 is detachably inserted into the probe 12. A part of the collection tube 20 on the other end 20b side is outside the probe 12 (see FIG. 2).

The collection tube 20 is preferably excellent in heat resistance and chemical resistance, and is made of, for example, a fluororesin such as polytetrafluoroethylene.
The thickness of the collection tube 20 is preferably set as thick as possible from the viewpoint of heat resistance. The inner diameter of the collection tube 20 is preferably set as large as possible so that the flow rate of the exhaust gas G can be secured.

As shown in FIGS. 1 and 2, the connection member 30 removably connects the other end 20 b of the collection tube 20 to the introduction tube 105 of the collection device 100. As shown in FIG. 2, the connection member 30 includes a covering tube 32, a first joint portion 35, a second joint portion 38, and a connection tube 40.
The covering tube 32 covers a portion of the collection tube 20 that is outside the probe 12. The covering tube 32 has flexibility. The covering tube 32 is made of, for example, silicon.

The first joint portion 35 is a member that detachably connects one end 32 a of the covering tube 32 to the probe 12. The first joint portion 35 is formed in a tubular shape. The collection tube 20 can be inserted into the first joint portion 35. The 1st joint part 35 has the external thread part (not shown) provided in the one end side, and the connection part 36 provided in the other end side.
The male screw portion is screwed into the large diameter portion 14 of the probe 12. The connection part 36 is configured in a cylindrical shape. The connecting portion 36 is detachably fitted to the one end 32 a side of the covering tube 32.

  The second joint portion 38 is a member that connects the other end 20 b of the collection tube 20 and the other end 32 b of the covering tube 32 and one end 40 a of the connection tube 40. The second joint portion 38 is formed in a tubular shape. The second joint portion 38 includes a locking portion 38a and a connection portion 38b extending on the opposite side of the locking portion 38a.

  The locking portion 38a connects the other end 20b of the collection tube 20 and the other end 32b of the cover tube 32 so that a predetermined gap is formed between the outer peripheral surface of the collection tube 20 and the inner peripheral surface of the cover tube 32. Lock. The connection part 38b is configured in a cylindrical shape. One end 40a of the connection tube 40 is attached to the outer peripheral surface of the connection portion 38b.

The connection tube 40 is a member that connects the connection part 38 b of the second joint part 38 and the introduction pipe 105 of the collection device 100. The connection tube 40 has flexibility. The connection tube 40 is made of, for example, silicon.
In addition, it is preferable to appropriately provide a sealing member that ensures airtightness at a location where the collection tube 20 and the connection tube 40 are connected.

  The exhaust gas collecting device 10 configured as described above is attached to a flange portion (not shown) or the like provided on the flow path wall 2.

Next, an ammonia collection method using the exhaust gas collection device 10 according to the present embodiment will be described with reference to FIG. The ammonia collection method is a method of collecting a part of the exhaust gas G flowing through the exhaust gas flow path 1 through the collection tube 20 of the exhaust gas collection device 10 and collecting ammonia contained in the exhaust gas G.
The ammonia collection method includes an exhaust gas introduction process, a collection tube removal process, and a collection tube cleaning process.

  The exhaust gas introduction step is a step of collecting a part of the exhaust gas G from the exhaust gas flow path 1 through the collection tube 20 and introducing a part of the exhaust gas G into the collection device 100. Specifically, by operating the pump 140, a part of the exhaust gas G in the exhaust gas passage 1 is sucked. Then, the exhaust gas G is introduced into the collection tube 20 through the opening 13 of the probe 12 and the opening 21 of the collection tube 20.

  The exhaust gas G is sequentially introduced into the absorption liquid 110 of the first absorption bottle 120 and the second absorption bottle 125 via the connection member 30 and the introduction pipe 105, and ammonia contained in the exhaust gas G is absorbed by the absorption liquid 110. The As a result, an analytical sample solution that does not take into account the ammonia adhering to the inside of the collection tube 20 (hereinafter referred to as “normal analytical sample solution”) can be obtained.

  The collection tube removing step is a step of removing one end 20a of the collection tube 20 inserted into the probe 12 from the probe 12 after the exhaust gas introduction step. Specifically, first, the covering tube 32 is removed from the connection portion 36 of the first joint portion 35, and then the collection tube 20 is pulled out from the probe 12, thereby opening the opening 21 of the collection tube 20 to the outside of the probe 12. Expose.

  In the collection tube washing step, washing water (for example, pure water) is injected into the opening 21 of the collection tube 20 that has been removed from the probe 12 in the collection tube removal step, and ammonia adhering to the inside of the collection tube 20 is removed. This is a step of introducing into the collection device 100 together with the washing water.

  Specifically, for example, cleaning water is injected into the opening 21 of the collection tube 20 using a polyethylene cleaning bottle. Then, the ammonia adhering to the inside of the collection tube 20 is washed away by the washing water and introduced into the first absorption bottle 120. That is, it is possible to collect a low amount of ammonia remaining in the probe, which has heretofore been difficult to collect.

  In the first absorption bottle 120, ammonia contained in the cleaning liquid is absorbed by the absorption liquid 110. As a result, an analysis sample solution for analyzing ammonia adhering to the inside of the collection tube 20 (hereinafter referred to as “high-precision analysis sample solution”) can be obtained.

  As described above, by analyzing the sample solution for normal analysis by, for example, indophenol blue absorptiometry, it is possible to measure the ammonia concentration when the ammonia adhering to the inside of the collection tube 20 is not taken into consideration. . Furthermore, the amount of ammonia adhering to the inside of the collection tube 20 can be measured by analyzing the sample solution for high accuracy analysis by, for example, indophenol blue absorptiometry.

According to the exhaust gas collecting instrument of the present embodiment described above, the following effects are exhibited.
In the exhaust gas collecting device 10 of the present embodiment, the probe 12 provided in the exhaust gas flow channel 1 and the one end 20a side are detachably inserted into the probe 12, and the other end 20b side is led out from the probe 12 to the collecting device 100. A sampling tube 20 to be connected.

  Therefore, it is possible to collect ammonia when the ammonia attached to the inside of the collection tube 20 is not considered. In addition, by washing the inside of the collection tube 20 removed from the probe 12 with washing water, it is possible to reliably collect ammonia attached to the inside of the collection tube 20. In other words, ammonia that was originally contained in the exhaust gas G but could not be collected because it was attached to the inside of the probe can be attached to the inside of the collection tube 20 and recovered (collected) by washing it with washing water. .

  Therefore, according to the exhaust gas collecting instrument 10 according to the present embodiment, it is possible to collect the low amount of ammonia remaining in the probe, which has been difficult to collect in the past, and to ensure the ammonia contained in the exhaust gas G. Can be collected. Thereby, the ammonia concentration of the exhaust gas G can be accurately measured.

  The collection tube 20 is made of a fluororesin. The fluororesin is excellent in heat resistance and chemical resistance. Therefore, it is possible to suppress the sampling tube 20 from being thermally deformed by the high temperature exhaust gas G or being eroded by the chemical substance contained in the exhaust gas G.

  Further, the exhaust gas collecting device 10 of the present embodiment includes a connecting member 30 that detachably connects the other end 20 b of the collecting tube 20 to the introduction pipe 105 of the collecting device 100. Therefore, the workability at the time of connecting with the collection apparatus 100 and the workability at the time of releasing the connection can be improved.

  In addition, the connection member 30 includes a covering tube 32 that covers the collection tube 20 led out from the probe 12. Therefore, the heat insulation of the collection tube 20 can be ensured, and the exhaust gas G flowing through the collection tube 20 can be prevented from condensing.

  Moreover, the covering tube 32 has flexibility. Therefore, when connecting the collection tube 20 to the collection device 100, the degree of freedom of the layout can be increased.

  The connecting member 30 further includes a first joint portion 35 provided on the probe 12 and detachably connecting one end 32a of the covering tube 32 to the probe 12. Therefore, the attaching / detaching operation of the probe 12 and the covering tube 32 can be easily performed.

  The probe 12 includes a handle portion 15 that can be gripped by an operator. Therefore, workability when attaching the probe 12 to the flow path wall 2 of the exhaust gas flow path 1 can be improved.

The ammonia collection method using the exhaust gas collection device 10 according to the present embodiment includes an exhaust gas introduction process, a collection tube removal process, and a collection tube cleaning process. Therefore, the ammonia adhering to the inside of the collection tube 20 can be washed and collected easily.
Therefore, according to the ammonia collection method using the exhaust gas collecting device 10 according to the present embodiment, it is possible to collect a small amount of ammonia remaining in the probe, which has been difficult to collect conventionally, and the exhaust gas G The concentration of ammonia contained in can be accurately measured.

As mentioned above, although one Embodiment of this invention was described, this invention is not restrict | limited to embodiment mentioned above, It can change suitably.
In the said embodiment, although the collection tube 20 demonstrated as what consists of a fluororesin, it is not limited to this. As long as predetermined heat resistance and chemical resistance are excellent with respect to the exhaust gas G, materials other than fluororesin may be used.

  Moreover, in the said embodiment, although the exhaust gas collection instrument 10 demonstrated as what is provided in the exhaust gas flow path 1 of the exit side of a denitration apparatus, it is not limited to this, In a coal-fired power plant, the flow path of the exhaust gas G It may be provided at an exit location, an entrance location, or the like of an electrostatic precipitator (not shown) installed.

G exhaust gas 1 exhaust gas flow path 10 exhaust gas collecting instrument 12 probe 13, 21 opening 15 handle part 20 sampling tube 20a one end 20b other end 30 connecting member 32 coated tube 32a one end 35 first joint part (joint part)
40 connecting tube 100 sampling device

Claims (3)

An exhaust gas collecting device for collecting a part of the exhaust gas from an exhaust gas flow channel through which exhaust gas containing ammonia flows, and introducing it into a collection device for collecting ammonia contained in the exhaust gas,
A probe having an opening for introducing a part of the exhaust gas, configured in a tubular shape, and provided in the exhaust gas flow path;
An opening for introducing the exhaust gas introduced into the probe is provided on one end side, and is configured in a tubular shape. The one end side is detachably inserted into the probe and the other end is led out from the probe. A flexible collection tube connected to the collection device;
With
The probes example Bei a and workers graspable handle portion has a pair of metal rods extending in a direction intersecting the direction of extension of the probe,
A connection member for detachably connecting the other end of the collection tube to the collection device;
The connection member includes a flexible coated tube that covers the sampling tube led out from the probe, and a joint portion that is provided on the probe and removably connects one end of the coated tube to the probe. Equipped exhaust gas collecting equipment.   The exhaust gas collecting device according to claim 1, wherein the collection tube is made of a fluororesin. Using the exhaust gas collecting device according to claim 1 or 2 , a part of the exhaust gas flowing through the exhaust gas passage is collected, and an ammonia collecting method for collecting ammonia contained in a part of the exhaust gas,
An exhaust gas introduction step of collecting a part of the exhaust gas from the exhaust gas flow path and introducing a part of the exhaust gas into the sampling device;
After the exhaust gas introduction step, a sampling tube removing step for removing one end of the sampling tube inserted into the probe from the probe,
Washing tube cleaning in which washing water is injected from the opening of the collecting tube removed from the probe in the collecting tube removing step, and the ammonia adhering to the inside of the collecting tube is introduced into the collecting device together with the washing water Process,
A method for collecting ammonia.

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