JP2005055247A - Exhaust gas measuring filter and gas sampler using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an exhaust gas measuring filter capable of certainly removing an interfering component and dust, which exert an adverse effect on the analyzed result of an exhaust gas or an analyzer, from the exhaust gas, having a compact constitution and easy in maintenance, and a gas sampler using it. <P>SOLUTION: In the exhaust gas measuring filter F constituted by providing a filter element 9 in a case 2 so as to remove dust contained in a sample gas S, a scrubber column 8 for removing an interfering component, which obstructs the measurement of a component to be measured, is arranged in the filter element 9 and a partition member 14, which extends from one end side of the scrubber column 8 toward the other end side thereof, is arranged in the scrubber column 8 to provide a plurality of housing parts 15 in the scrubber column 8. A scrubber substance 7 is provided in the respective housing parts 15. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  For example, when a part of combustion exhaust gas discharged from a boiler or the like is sampled as sample gas and supplied to the gas analyzer, the present invention is arranged upstream of the gas analyzer such as a sampling point of the sample gas. The present invention relates to an exhaust gas measurement filter and a gas sampling device using the same.

Japanese Patent Publication No. 56-24891 Japanese Utility Model Publication No. 56-129815

For example, a part of combustion exhaust gas (hereinafter simply referred to as exhaust gas) discharged from a boiler that burns coal into a flue is sampled, and this is continuously supplied as a sample gas to an SO ₂ analyzer, and the exhaust gas The SO ₂ in it is continuously analyzed.

By the way, dust such as dust and soot is mixed in the exhaust gas, and NH ₃ or SO ₃ salt mist (SO ₃ and metal mist-like reaction generation as interference components that interfere with SO ₂ measurement) Etc.). The dust has a disadvantage of shortening the maintenance cycle of the SO ₂ analyzer, and NH ₃ and SO ₃ mist adversely affect the analysis result of SO ₂ .

Therefore, conventionally, an attempt was made to remove the dust, NH _{3 and the} like as much as possible using a gas sampling device as shown in FIG. That is, in this figure, 31 is a flue and the exhaust gas G is flowing as shown by the arrow. Reference numeral 32 denotes a probe tube for gas sampling as a gas sampling part inserted and disposed in the flue 31, and a filter element 34b is accommodated in a case 34a in a sample gas flow path 33 downstream of the probe tube 32. An exhaust gas measurement filter 34 and a scrubber column 35b for removing an interference component such as NH ₃ are accommodated in the case 35a, a scrubber unit 35 heated to an appropriate temperature is provided, and the exhaust gas measurement filter 34 is provided. And the scrubber unit 35 are connected by a heating pipe 36, and the downstream outlet of the scrubber unit 35 is connected to an SO ₂ analyzer 38 via a heating pipe 37.

In the gas sampling apparatus having the above-described configuration, a part of the exhaust gas G flowing through the flue 31 is sampled by the probe tube 32 to become the sample gas, enters the sample gas flow path 33, and is provided on the upstream side thereof. When passing through the filter 34, dust is removed, and further, through the heating pipe 36, the dust enters the scrubber unit 35. When passing through this, interference components such as NH ₃ and SO ₃ salt mist are removed. Then, the sample gas from which dust and interference components have been removed is introduced into the SO ₂ analyzer via the heating pipe 38 and is subjected to SO ₂ analysis.

  However, in the conventional gas sampling device, the exhaust gas measurement filter 34 and the scrubber unit 35 are provided independently of each other, and they are connected by the heating pipe 36, so that a large space is required for installing them. However, there is a disadvantage that the gas sampling apparatus has to be enlarged accordingly.

  Further, as described above, since the exhaust gas measurement filter 34 and the scrubber unit 35 are provided independently of each other, maintenance of the exhaust gas measurement filter 34 and maintenance of the scrubber unit 35 must be performed separately. It took a long time for maintenance.

Further, when SO ₃ salt mist as an interference component is contained in the sample gas, the SO ₃ salt mist is first captured by the exhaust gas measurement filter 34, moisture drying occurs, and the SO ₃ salt mist is decomposed. As a result, SO ₂ gas is generated. The decomposition reaction of the SO ₃ salt mist trapped in the exhaust gas measurement filter 34 is extremely unstable. When a large amount is accumulated over a long period of time, the analysis instruction value corresponds to several times the actual value of SO _2. May be a value.

Similarly to the case of analyzing SO ₂ in exhaust gas, when analyzing NO _X and O ₂ in exhaust gas, interference components such as NH ₃ and SO ₃ salt mist and dust are also extracted from the exhaust gas. The above-mentioned inconvenience occurred in the gas sampling device used for analyzing SO ₂ in exhaust gas, which has been removed, is a gas sampling device for analyzing NO _X and O _{2 in} exhaust gas. In the same way.

  The present invention has been made in consideration of the above-mentioned matters, and its purpose is to reliably remove interference components and dust that adversely affect the analysis results of the exhaust gas and the analysis apparatus from the exhaust gas, and to have a compact configuration. Therefore, it is an object to provide an exhaust gas measurement filter that can be easily maintained and a gas sampling device using the same.

  In order to achieve the above object, an exhaust gas measurement filter according to the present invention is provided with a filter element in a case, wherein the filter element is configured to remove dust contained in a sample gas. A scrubber column for removing an interference component that interferes with measurement of the measurement target component is disposed inside, and a partition member extending from one end side to the other end side of the scrubber column is disposed in the scrubber column. A plurality of accommodating portions are formed in the scrubber column, and a scrubber substance is provided in each accommodating portion (claim 1).

  It is preferable that the filter element has a cylindrical shape and has an uneven filtration surface in the outer peripheral direction (Claim 2).

  A coarse filter may be provided on one end side and the other end side in the scrubber column.

  And in order to achieve the said objective, the gas sampling apparatus of this invention has provided the filter for exhaust gas measurement in any one of Claims 1-3 in the gas sampling flow path of the downstream of a gas sampling part. (Claim 4).

  According to the first aspect of the present invention, it is possible to obtain an exhaust gas measurement filter that can reliably remove dust and interference components while having a compact configuration and easy maintenance.

  Specifically, in the invention according to claim 1, in the exhaust gas measurement filter provided with a filter element in the case and configured to remove dust contained in the sample gas, a measurement object is provided inside the filter element. Since a scrubber column is installed to remove interference components that interfere with component measurement, the installation space for the scrubber column and filter element is smaller than when the scrubber column and filter element are housed in separate cases. In addition, since the number of constituent members is reduced as compared with the case where the scrubber column and the filter element are accommodated in separate cases, the configuration becomes very compact.

  In the invention according to claim 1, since the scrubber column and the filter element are provided in the same case, the efficiency of maintenance work such as replacement of the scrubber column and the filter element is dramatically improved.

  Furthermore, in the invention which concerns on Claim 1, the partition member extended toward the other end side from the one end side of a scrubber column is arrange | positioned in the said scrubber column, a some accommodating part is formed in a scrubber column, Since the scrubber substance is provided in the above, the following effects can be obtained. That is, even when the scrubber column is arranged in the vertical direction (vertical direction), for example, when the other end side is positioned upward, a gap where no scrubber substance is present is formed on the other end side in the scrubber column. The interference component in the sample gas passing through the scrubber column reliably comes into contact with the scrubber substance filled in the portion excluding the gap in the scrubber column, so there is no inconvenience.

  By the way, when the scrubber column is arranged in the horizontal direction (horizontal direction), if a gap is formed in the upper part of the scrubber column from the one end side to the other end side of the scrubber column, the scrubber substance does not exist. Since the interference component in the sample gas does not come into contact with the scrubber substance, the removal efficiency of the interference component is lowered. In the invention according to claim 1, a partition member is disposed in the scrubber column, and this partition member Since the scrubber material is provided in each of the storage portions formed by the above, no gaps as described above are formed in the scrubber column even when the scrubber column is disposed sideways. The contact between the interference component and the scrubber substance is satisfactorily performed, and the removal efficiency of the interference component is greatly improved. Therefore, in the invention according to claim 1, an exhaust gas measurement filter can be obtained regardless of the mounting direction.

  As described in claim 2, when the filter element is configured to have an uneven filtration surface in the outer peripheral direction, the filtration area of the filter element becomes larger, and accordingly, dust contained in the sample gas and Substances to be removed, such as interference components and reaction products of scrubber substances, can be more reliably removed, and the life of the filter element itself is increased.

  As described in claim 3, when the coarse filters provided on one end side and the other end side in the scrubber column are provided, the coarse filter allows the dust contained in the sample gas, the reaction product, or the scrubber substance to be contained. It is possible to more reliably remove a substance to be removed such as a granular material that is generated when a part thereof is shaved or crushed.

  In the invention according to claim 4, the sample gas from which the removal target substance is removed as much as possible by the exhaust gas measurement filter can be supplied to the gas analysis device. It is possible to obtain a gas sampling device that can perform accurate analysis stably over a long period of time and can keep the frequency of maintenance of the gas analyzer low.

  1 and 2 show a first embodiment of the present invention.

In FIG. 1, D is a gas sampling device that collects a part of exhaust gas discharged from a boiler or the like as sample gas S and supplies this sample gas S to gas analyzer A. In this embodiment, a case where exhaust gas discharged from a boiler and flowing through a flue (not shown) using the gas sampling device D is sampled as sample gas S and SO ₂ in the sample gas S is analyzed is shown.

The gas sampling device D includes a gas sampling probe tube 1 as a gas sampling unit, and a gas analyzer A for measuring a measurement target component (SO ₂ ) in the sample gas S from the probe tube 1. And an exhaust gas measurement filter F for removing interference components and dust that interfere with measurement of the measurement target component from the sample gas S collected by the probe tube 1. Yes. In this embodiment, the exhaust gas measurement filter F is provided integrally with the probe tube 1. In other words, the exhaust gas measurement filter F is provided upstream of the gas sampling flow path 5. Yes.

  The probe tube 1 is made of a corrosion-resistant material, and is detachably attached to a wall body (not shown) constituting a boiler flue. Specifically, the probe tube 1 is attached to the wall body so as to be inserted therethrough, and is configured so that the exhaust gas flowing in the flue from its tip can be taken in as the sample gas S satisfactorily. Further, a flange 1a is provided on the outer peripheral surface of the probe tube 1 so that the probe tube 1 can be attached to the wall body satisfactorily.

  The exhaust gas measurement filter F is used to heat and keep the case 2 made of a corrosion-resistant material, the unit 3 accommodated in the case 2, and the case 2 at an appropriate temperature (for example, 150 to 200 ° C.). For example, a heating and heat retaining means 4 made of an appropriate heating heater.

  The case 2 includes a substantially cylindrical (cylindrical in this embodiment) side wall 2a, a blocking wall 2b connected to one end side (upstream side) of the side wall 2a, and the other end side (downstream side) of the side wall 2a. ) Is detachably attached to the lid 2c. In this embodiment, a male screw portion (not shown) is provided on one of the other end side of the side wall 2a and the lid 2c, and a female screw portion that is screwed to the male screw portion (not shown) is provided on the other side. The lid 2c is attached to the other end of the side wall 2a by screwing the male screw portion and the female screw portion.

  The closed wall 2b is provided with a gas introduction part 2d communicating with the probe tube 1, and the side wall 2a is configured to have an appropriate temperature by an appropriate heating and keeping means (not shown). A gas outlet 2e connected to the gas analyzer A via the gas sampling channel 5 is provided.

  The lid 2c is attached so as to airtightly close the opening at the other end of the side wall 2a, and a handle 2f is provided on the outside of the lid 2c.

  The inner diameter of the gas introduction part 2d is set to be substantially the same as or slightly larger than the inner diameter of the opening 6a of the cylinder 6 to be described later, and the inner diameter of the gas lead-out part 2e is the same as that of the gas introduction part 2d. It is set to approximately the same as the inner diameter of.

  The closed wall 2b of the case 2 and the probe tube 1 may be integrally formed or may be formed separately. Further, when the closed wall 2b of the case 2 and the probe tube 1 are formed as separate bodies, they may be configured to be directly connected to each other, or may be connected via a joint member or an appropriate heating pipe. It may be configured.

  The unit 3 is integrally provided with a scrubber column 8 having a cylindrical body 6 and a scrubber material 7 disposed in the cylindrical body 6, and a filter element 9 disposed so as to cover the scrubber column 8. 2 is detachably accommodated. That is, the unit 3 is configured as a so-called cartridge type suitable for disposable or recycling use.

  As shown in FIG. 2, the cylindrical body 6 is substantially cylindrical, has an opening 6a at one end, is closed at the other end by a closing portion 6b, and has a plurality of through holes 6c in the peripheral wall near the other end. 6d, a flange portion 6e provided on one end side of the main body portion 6d, and a flange portion 6f provided on the other end side of the main body portion 6d. It is made of a heat-resistant material such as stainless steel. Further, a bent portion 6g is provided at the peripheral edge of the flange portions 6e and 6f.

  The flange portion 6f and the closing portion 6b provided on the other end side of the main body portion 6d may be integrally formed or formed separately. Further, the main body portion 6d and the closing portion 6b may be formed integrally or separately. Furthermore, the main body portion 6d and the flange portions 6e and 6f may be formed integrally or separately.

  When the sample gas S comes into contact with the scrubber substance 7, it does not affect the measurement target component contained in the sample gas S, and converts or collects the interference component contained in the sample gas S into another component. For example, a reaction liquid that reacts with the interference component to convert the interference component into a component that does not interfere with the measurement of the measurement target component is prepared. , Impregnated with an inert porous material.

In this example, since the measurement target component of the gas analyzer A is acidic SO ₂ , it does not react with this SO _2, and is non-volatile that easily reacts with NH ₃ or SO ₃ salt mist that is an interference component. It is preferable that the scrubber material 7 is made up of an acidic material, for example, activated carbon or porous silica impregnated with high-concentration phosphoric acid (H ₃ PO ₄ ) is used as the scrubber material 7.

  As shown in FIG. 1, the scrubber column 8 includes a net-like pressing member 12 a, a coarse filter 13 a, a scrubber substance 7, and a partition member 14 in order from the other end side in the main body portion 6 d of the cylindrical body 6. A coarse filter 13b and a net-like pressing member 12b are arranged (accommodated).

  The holding members 12a and 12b are for holding the scrubber substance 7, the coarse filters 13a and 13b and the partition member 14 in a state of being accommodated in the main body 6d, and are made of a material having corrosion resistance and heat resistance. Become. The pressing member 12a disposed on the other end side of the main body portion 6d is positioned closer to the one end side than the through hole 6b so as not to block the through hole 6b provided on the other end portion of the main body portion 6d. Placed in.

  The coarse filters 13a and 13b are respectively provided at upstream and downstream positions of the scrubber material 7 in the sample gas flow path formed in the main body 6d. For example, the coarse filters 13a and 13b Made of heat-resistant material.

  The partition member 14 is made of a material having corrosion resistance and heat resistance, and is arranged in a state extending from one end side to the other end side in the main body portion 6d. As shown in FIG. 4, the storage unit 15 is divided into, for example, four), and the storage unit 15 is filled with the scrubber substance 7.

  Specifically, the partition member 14 is formed by combining a plurality of plate-like bodies 16 extending from one end side toward the other end side in the main body portion 6d in a substantially cross shape in cross section. Each plate-like body 16 includes a base portion 16a formed substantially in a plane and a curved end portion 16b provided continuously to the base portion 16a.

  The filter element 9 is made of a material having corrosion resistance and heat resistance, and is made of a net having an appropriate scale capable of reliably removing dust and products (described later) to be removed from the sample gas S. It is formed in a cylindrical shape. The filter element 9 is attached so as to cover the outer peripheral surface of the main body portion 6d of the cylindrical body 6, and both ends thereof are held by the flange portions 6e and 6f of the cylindrical body 6, and both end portions of the filter element 9 and the flange It is comprised so that a clearance gap may not be formed between the parts 6e and 6f.

  Further, the filter element 9 has an uneven filtration surface formed in the outer peripheral direction, and in this embodiment, the filtration surface is formed in a substantially pleated shape.

  In the case 3 having the above-described configuration, the opening 6a on one end side of the main body portion 6d of the cylindrical body 6 faces the gas introduction portion 2d of the case 2 in the case 2, and the cylindrical body 6 The closing part 6b provided on the other end side of the main body part 6d is accommodated so as to face each other. At this time, a ring-shaped seal packing 17a having an inner diameter slightly larger than the inner diameter of the main body portion 6d of the cylindrical body 6 is disposed between the flange portion 6e of the cylindrical body 6 and the closing wall 2b of the case 2. Between the flange portion 6f of the cylindrical body 6 and the lid body 2c of the case 2, a ring-shaped seal packing 17b whose inner diameter is slightly larger than the inner diameter of the main body portion 6d of the cylindrical body 6 is disposed. That is, the seal packing 17a is configured to prevent gas from flowing between the flange portion 6e and the closed wall 2b of the case 2, and the seal packing 17b allows the flange portion 6f and the lid 2c of the case 2 to It is comprised so that gas may not circulate between.

  The unit 3 can be easily mounted in the case 2 by removing the lid 2c provided on the other end side of the side wall 2a and inserting it from the other end side of the side wall 2a. 2 can be easily removed from the other end side of the side wall 2a by removing the lid 2c provided on the other end side of the side wall 2a. That is, the unit 3 is detachably provided in the case 2.

  Further, a suction pump (not shown) that can always suck a certain amount of the sample gas S is provided at an appropriate position of the gas sampling flow path 5 or downstream of the gas analyzer A.

  Next, the operation of the gas sampling device D having the above configuration will be described.

  First, in a state where the probe tube 1 is attached to the wall constituting the boiler flue, the heating and heat retaining means 4 is activated to bring the inside of the case 2 to a predetermined temperature. When the suction pump is operated in this state, a part of the exhaust gas flowing through the flue is sampled by the probe tube 1 and becomes the sample gas S and travels downstream in the probe tube 1. Enter case 2.

  The sample gas S that has entered the case 2 first enters the scrubber column 8 from the opening 6a on one end side of the main body portion 6d of the cylindrical body 6, and the holding member 12a and the rough member 12a disposed on one end side in the main body portion 6d. It passes through the filter 13a. When the sample gas S passes through the coarse filter 13a, dust having a relatively large particle size contained in the sample gas S is collected by the coarse filter 13a and removed from the sample gas S.

Subsequently, the sample gas S advances downstream while contacting the scrubber substance 7 filled in each accommodating portion 15 of the main body portion 6 d of the cylindrical body 6. At this time, SO ₂ which is a measurement target component in the sample gas S does not react with the scrubber substance 7 (high concentration H ₃ PO ₄ ), but NH ₃ and SO which are interference components in the sample gas S. ₃ salt mist (here, represented as MSO _3), the high concentration of H ₃ PO ₄ 7 respectively below (1), reacts as (2).
NH ₃ + H ₃ PO ₄ → NH ₄ H ₂ PO ₄ (1)
MSO ₃ + H ₃ PO ₄ → MHPO ₄ + SO ₂ ↑ + H ₂ O (2)

As shown in the above formulas (1) and (2), NH ₃ and SO ₃ salt mist MSO ₃ which are interference components react with high-concentration H ₃ PO ₄ which is a scrubber substance 7, respectively, and phosphoric acid. A powdery reaction product similar to dust, such as ammonium and weak acid salt, is produced, and these reaction products proceed together with the sample gas S to the other end side in the scrubber column 8 (each accommodating portion 15).

  Furthermore, the sample gas S in a state containing the reaction product passes through the pressing member 12b and the coarse filter 13b disposed on the other end side in the main body 6d. At this time, among the reaction products contained in the sample gas S, those having a relatively large particle size are collected by the coarse filter 13 b and removed from the sample gas S. Further, the scrubber substance 7 accommodated in the main body 6d is in a state where a part thereof is scraped or crushed by an impact applied during the conveyance, and the fine scrubber generated in this way. The substance 7 is also collected by the coarse filter 13b.

And the sample gas S which passed the coarse filter 13b is derived | led-out from the through-hole 6c of the main-body part 6d to the outer side of the main-body part 6d, and then passes the filter element 9 from the inner side to the outer side. During this passage, the dust in the sample gas S and the reaction product that could not be collected by the coarse filters 13a and 13b are collected by the filter element 9, and the SO ₂ is measured from the sample gas S. Interfering interference components and dust that adversely affects the gas analyzer A are removed, and in this state, the sample gas S is led out of the case 2 from the gas lead-out part 2e, and passes through the gas sampling channel 5 to the gas analyzer A. Supplied.

In the exhaust gas measurement filter F having the above-described configuration, the members constituting the case 2 and the unit 3 are all made of a heat-resistant material, and the inside of the case 2 is brought to a high temperature state of 150 to 200 ° C. by the heat insulation means 4. Therefore, the moisture in the sample gas S does not condense and becomes drainage, and it is possible to avoid the inconvenience that the function of the scrubber column 8 is lowered by this drainage. And, by providing the heat insulation means 4, the scrubber column 8 is heated and kept at a predetermined temperature, the reaction with NH ₃ or SO ₃ salt mist is reliably performed, and these interference components are surely removed. Can do.

  Further, since the inner diameters of the gas introduction part 2d and the gas lead-out part 2e of the case 2 are set to be sufficiently large, clogging such as dust and interference components in the gas introduction part 2d and the gas lead-out part 2e hardly occurs. Therefore, the life of the gas sampling device D is not shortened due to the deterioration due to the clogging, and can be used reliably until the life setting period.

  Further, the exhaust gas measurement filter F is configured such that the sample gas S passes through the body 6d (scrubber column 8) of the cylindrical body 6 from one end side to the other end side, and then passes through the filter element 9. Therefore, the interference component contained in the sample gas S can be brought into wide contact with the scrubber substance 7 accommodated in the cylinder 6, and the interference component can be removed more reliably.

  Further, in the gas sampling device D provided with the exhaust gas measurement filter F, the cartridge type unit 3 is configured by integrally combining the scrubber column 8 and the filter element 9 which are consumables and require maintenance such as replacement. Therefore, compared with the conventional sampling apparatus which accommodated the scrubber column 8 and the filter element 9 in separate cases, it becomes a more compact configuration, and maintenance work such as replacement of the scrubber column 8 and the filter element 9 can be performed. Efficiency is also improved.

In the gas sampling device D of the above-described embodiment, the sample gas S is filtered by the filter element 9 after passing the sample gas S through the scrubber column 8. Conversely, the sample gas S is filtered by the filter element 9. Then, it may be passed through the scrubber column 8. A gas sampling apparatus D ₂ according to the second embodiment configured as described above is shown below.

  FIG. 3 shows a second embodiment of the present invention. In FIG. 3, the same members as those shown in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

The gas sampling device D ₂ of the second embodiment includes a probe tube 1 and a measurement exhaust gas filter F ₂ .

The measurement exhaust gas filter F ₂ is mainly different from the measurement exhaust gas filter F of the first embodiment in that the unit 3 is accommodated in the case 2 in the opposite direction. The configuration of case 2 is slightly changed. Therefore, the case 2 of this embodiment having a slightly different configuration from the case 2 of the first embodiment is hereinafter referred to as case 2 ′.

  The case 2 ′ is compared with the case 2 in that the side wall 2 a is composed of two cylindrical side wall portions 2 h and 2 i having the same inner diameter and outer diameter, and a holding portion 2 j is provided in the side wall portion 2 i. It differs in that it is provided.

  Specifically, the side wall 2h located on the upstream side and the side wall 2i located on the downstream side constituting the side wall 2a are not shown in detail, but a flange portion formed on the opening side via a packing or the like. Are separated by bolts and nuts.

  The side wall 2h is considerably longer than the side wall 2i located on the downstream side, and in this embodiment, the side wall 2h has the same length as the filter element 9.

  In the vicinity of the opening of the side wall 2i, a plate-like holding portion 2j for holding the cylindrical body 2 is provided vertically along the inner wall of the side wall 2i and toward the inside of the side wall 2i. In the center of the holding portion 2j, a hole 2k having an inner diameter substantially the same as the inner diameter of the main body 2d of the cylindrical body 2 is provided. In addition, it is comprised so that gas may not distribute | circulate between the said holding | maintenance part 2j and the side wall part 2i.

  The gas outlet 2e is provided on the side wall 2i, and the gas outlet 2e is provided at a position on the other end side (downstream side) of the case 2 with respect to the holding part 2j.

  The unit 3 has a holding portion for holding the case 2 ′ in the case 2 ′, with a closing portion 6 b for closing the other end of the main body portion 6 d of the cylindrical body 6 facing the gas introduction portion 2 d of the case 2 ′. The opening 6a provided on one end side of the main body 6d of the cylindrical body 6 is accommodated in the hole 2k of 2j (that is, in a direction opposite to the direction shown in FIG. 1). At this time, a spacer 18 having an appropriate shape that allows gas to flow between the flange portion 6f and the closing wall 2b is provided between the flange portion 6f of the cylindrical body 6 and the closing wall 2b of the case 2. Between the flange portion 6e of the cylindrical body 6 and the holding portion 2j of the case 2, a ring-shaped seal packing 19 having an inner diameter substantially equal to the inner diameter of the main body portion 6d of the cylindrical body 6 is disposed. That is, the seal packings 17a and 17b in the first embodiment are not provided. Further, the seal packing 19 prevents the gas from flowing between the flange portion 6e and the holding portion 2j of the case 2.

The following describes the operation of the gas sampling device D ₂ of the second embodiment configured as described above.

First, in a state where the probe tube 1 is attached to the wall constituting the boiler flue, the heating and heat retaining means 4 is activated to bring the inside of the case 2 to a predetermined temperature. When the suction pump is operated in this state, a part of the exhaust gas flowing through the flue is sampled by the probe tube 1 and becomes the sample gas S and travels downstream in the probe tube 1, and the exhaust gas measurement filter F ₂ Enter case 2 '. The process so far is the same as in the first embodiment.

  The sample gas S that has entered the case 2 ′ first collides with the closed portion 6 b of the cylindrical body 6, passes between the flange portion 6 f of the cylindrical body 6 and the closed wall 2 b of the case 2, and outside the filter element 9. And pass through the filter element 9 from the outside to the inside. During the passage, the dust contained in the sample gas S is collected by the filter element 9 and removed from the sample gas S.

  Subsequently, the sample gas S is introduced from the through hole 6c of the main body 6d to the inside of the main body 6d (scrubber column 8), and the pressing member 12b and the coarse filter 13b disposed on the other end side in the main body 6d. Pass through.

  Thereafter, the sample gas S advances downstream while contacting the scrubber substance 7 filled in the chambers 15 of the main body 6d of the cylindrical body 6. At this time, as described above, reaction products in the form of powder are generated, and these reaction products travel together with the sample gas S in the respective accommodating portions 15 of the scrubber column 8 to the downstream side.

  And the sample gas S which became the state containing the said reaction product passes the holding member 12a and the coarse filter 13a which are arrange | positioned at the one end side in the main-body part 6d. At this time, the reaction product contained in the sample gas S is collected by the coarse filter 13 a and removed from the sample gas S. Further, the scrubber substance 7 accommodated in the main body 6d is in a state where a part thereof is scraped or crushed by an impact applied during the conveyance, and the fine scrubber generated in this way. The substance 7 is also collected by the coarse filter 13b.

The sample gas S that has passed through the coarse filter 13a is in a state in which interference components that interfere with the measurement of SO ₂ and dust that adversely affects the gas analyzer A have been removed. It is led out of the case 2 from the part 2 e and supplied to the gas analyzer A through the gas sampling channel 5.

The effect obtained by the exhaust gas measurement filter F _{2 of} the second embodiment having the above-described configuration and the gas sampling device D ₂ provided with the exhaust gas measurement filter F ₂ is the same as that of the exhaust gas measurement filter F of the first embodiment. Since the effect is similar to that obtained by the sampling device D, the description thereof is omitted.

Further, both the exhaust gas measurement filter F of the first embodiment and the exhaust gas measurement filter F ₂ of the second embodiment bring the sample gas S into contact with the scrubber substance 7 in the cylindrical body 6 to cause interference components in the sample gas S. While the sample gas S is filtered by the filter element 9 to remove dust from the sample gas S, the exhaust gas measurement filter F ₂ of the second embodiment is particularly suitable for the sample gas S. This is effective when the dust contains a relatively large amount of dust.

That is, in the exhaust gas measurement filter F _{2 of} the second embodiment, the sample gas S first passes through the filter element 9, whereby dust in the sample gas S can be removed, and dust is contained in the scrubber column 8. Since the removed sample gas S is introduced, it is effectively prevented that dust is attached to the scrubber material 7 to cause a reduction in the capture efficiency of NH ₃ or SO ₃ salt mist.

The unit 3 having the same configuration can be used for both the exhaust gas measurement filters F and F ₂ of the first embodiment and the second embodiment only by changing the direction thereof. Since the difference between the case 2 and the case 2 ′ of the second embodiment is also slight, in the exhaust gas measurement filters F and F _{2 of the} present invention, the sample gas S passes through the scrubber column 8 and then passes through the filter element 9. It is possible to easily switch between the state and the state in which the sample gas S passes through the filter element 9 and then passes through the scrubber column 8.

The exhaust gas measurement filter F (F ₂ ) and the sampling device D (D ₂ ) of the present invention are also used when analyzing NO _x such as NO and NO ₂ which are acidic substances contained in the exhaust gas. Can do. When analyzing this NO _X, by sampled sample gas S is configured to pass through the NO _X converter converts the NO ₂ contained in the sample gas S to NO, then the sample gas S NO Although introduction into an analyzer is performed, NH ₃ or SO ₃ salt mist also functions as an interference component in such NO _x measurement. Therefore, when analyzing NO _X contained in the exhaust gas, as shown in FIG. 4, for example, a NO _X converter 20 is provided in the gas sampling flow path 5 connected to the downstream side of the exhaust gas measurement filter F, Instead of the gas analyzer A, a gas analyzer A ′ for analyzing NO may be provided on the downstream side.

The present invention is not limited to the above-described embodiment, and can be implemented with various modifications. For example, not only the probe tube 1 but also the exhaust gas measurement filters F and F ₂ may be arranged in the flue. In this way, it is not always necessary to provide the heat and heat retaining means 4, and even if it is provided, the power supplied to the heater constituting the heat and heat retaining means 4 may be small.

  The filter element 9 may have a cylindrical shape other than a cylindrical shape, and the shape of the filtration surface is not limited to a pleated shape, and is, for example, a bellows shape in which a mountain fold portion and a valley fold portion are alternately provided in the axial direction. Alternatively, a shape in which a plurality of projections and depressions are provided on a cylindrical net may be used.

  The coarse filters 13a and 13b may have appropriate strength, and the coarse filters 13a and 13b may be configured to hold the scrubber substance 7 and the partition member 14 in the main body 6d of the cylindrical body 6. In this case, The pressing members 12a and 12b can be omitted.

  The number of plate-like bodies 16 constituting the partition member 14 is not limited to four, and may be three or less, or five or more. Further, the shape of the plate-like body 16 is not limited to the above-described one. For example, as shown in FIG. 5A, the end portion 16b is formed in a substantially planar shape so that the cross section has a substantially bowl shape. The whole plate-like body 16 may be formed in a flat plate shape as shown in FIG. 5 (B), or as shown in FIG. 5 (C). The entire cross section of the body 16 may be streamlined (curved). Moreover, as shown in FIG. 6, each plate-like body 16 may have a shape twisted from one end to the other end. Moreover, you may shape | mold the some plate-shaped body 16 which comprises the partition member 14 not separately but integrally. Furthermore, the partition member 14 may be formed of a net-like body instead of the plate-like body 16. In this case, of course, the mesh size is set so as to be suitable for accommodating the scrubber substance 7.

It is explanatory drawing which shows roughly the structure of the gas sampling apparatus provided with the exhaust gas filter for a measurement which concerns on 1st Example of this invention. It is a longitudinal cross-sectional view which shows the structure of the said exhaust gas filter for a measurement roughly. It is explanatory drawing which shows roughly the structure of the gas sampling apparatus provided with the exhaust gas filter for a measurement which concerns on 2nd Example of this invention. It is an explanatory view schematically showing the structure of the gas sampling device when used in the NO _X measurements in the exhaust gas. (A), (B) and (C) are longitudinal sectional views schematically showing the configuration of a modification of the partition member used in the present invention. It is a perspective view which shows roughly the structure of the other modification of the said partition member. It is explanatory drawing which shows the structure of the conventional gas sampling apparatus roughly.

Explanation of symbols

2 Case 7 Scrubber material 8 Scrubber column 9 Filter element 14 Partition member 15 Housing F Filter for exhaust gas measurement

Claims (4)

  An exhaust gas measurement filter having a filter element in a case and configured to remove dust contained in a sample gas, and removing an interference component that disturbs measurement of a measurement target component in the filter element A scrubber column is disposed in the scrubber column, and a partition member extending from one end side to the other end side of the scrubber column is disposed in the scrubber column to form a plurality of housing portions in each scrubber column. A filter for exhaust gas measurement, characterized by providing a scrubber substance.   The filter for exhaust gas measurement according to claim 1, wherein the filter element has a cylindrical shape and has an uneven filtration surface in an outer peripheral direction thereof.   The exhaust gas measurement filter according to claim 1 or 2, wherein a coarse filter is provided on one end side and the other end side in the scrubber column.   A gas sampling apparatus, wherein the exhaust gas measurement filter according to any one of claims 1 to 3 is provided in a gas sampling flow path on the downstream side of the gas sampling section.

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