JP4452493B2 - Gas analysis pretreatment equipment - Google Patents

Description

  The present invention relates to a gas analysis pretreatment apparatus that performs a pretreatment such as removal of a mixture in a gas prior to the analysis of the gas, and particularly relates to an improvement for enhancing the response.

2. Description of the Related Art Gas analyzers that detect and quantify gas (gas) using absorption of infrared rays having a specific wavelength by gas molecules are known. Such a gas analyzer is suitably used for measuring various exhaust gases and components of gases contained in the atmosphere, and usually performs pretreatment such as removal of the mixture in the gases prior to analysis. It is required to do. For this reason, gas analysis pretreatment apparatuses having various configurations according to purposes have been proposed. For example, a configuration for improving durability described in Patent Document 1, a configuration for removing NH ₃ and organic compounds for analyzing NO _X components described in Patent Document 2, and Patent Document 3 The mixture which does not participate in the analysis is previously removed by these gas analysis pretreatment devices.

  However, a gas analysis pretreatment apparatus having a configuration that can remove the mixture contained in the sample gas as much as possible and can withstand long-term use requires a correspondingly large volume (venting chamber), and the responsiveness deteriorates. That was a problem. In particular, when the conventional gas analysis pretreatment device is applied to a device that detects a sample gas with a response of the order of several ms, such as the infrared gas analyzer described in Patent Document 4, the response is at least There was a problem of worsening over 1000 times. That is, it has been desired to develop a gas analysis pretreatment apparatus that is applicable to such a highly responsive gas analyzer and has excellent responsiveness.

Japanese Patent Laid-Open No. 10-38768 Japanese Patent No. 3064175 JP 2000-105175 A JP 2002-267596 A

  The present invention has been made against the background of the above circumstances, and an object of the present invention is to provide a gas analysis pretreatment apparatus having excellent responsiveness.

In order to achieve such an object, the gist of the present invention is that a housing having a larger cross-sectional area than an inlet and an outlet and having a vent chamber through which a gas from the inlet to the outlet can pass is formed. A gas analysis pretreatment apparatus comprising: a filter medium disposed in the ventilation chamber in the housing; and removing the mixture contained in the gas by passing the filter medium prior to the analysis of the gas, A drift plate for suppressing the flow of the gas in the central portion of the cross section of the vent chamber is provided adjacent to the upstream side of the filter medium , and the drift plate has the gas flow at the peripheral edge of the cross section of the vent chamber. An annular opening for guiding is provided penetrating in the thickness direction.

In this case, the drift plate for suppressing the flow of the gas in the central portion of the cross section of the vent chamber is provided adjacent to the upstream side of the filter medium , and the drift plate includes a peripheral edge portion of the cross section of the vent chamber. Since the annular opening for guiding the gas flow is provided in the thickness direction, the gas stagnation in the ventilation chamber can be effectively eliminated, and the gas is contained in the gas by the filter medium. The mixture is efficiently removed. That is, it is possible to provide a gas analysis pretreatment apparatus having excellent responsiveness.

Here, preferably, the drift plate has a tapered surface that spreads conically from the downstream side toward the upstream side. In this way, the gas flow along the tapered surface can more effectively eliminate the stagnation of the gas in the ventilation chamber, and can increase the contact area of the gas in the filter medium . There is an advantage that the removal efficiency of the mixture contained in can be increased.

Preferably, the area of the opening of the drift plate is larger than the cross-sectional area of the inlet. In this way, there is an advantage that high responsiveness can be secured without increasing the flow path resistance in the ventilation chamber.

Preferably, the vent chamber has an upstream space that spreads in a conical shape having an obtuse angle from the inlet toward the opening of the drift plate . In this way, there is an advantage that the gas stagnation in the ventilation chamber can be more effectively eliminated.

  Preferably, the apex angle is such that the cross-sectional area of the gas in the upstream space is larger than the cross-sectional area of the inlet. In this way, there is an advantage that high responsiveness can be secured without increasing the channel resistance in the upstream space.

  Preferably, the apex angle is a maximum angle that makes a cross-sectional area of the gas flow path in the upstream space larger than a cross-sectional area of the inlet. In this way, in addition to ensuring high responsiveness without increasing the flow path resistance in the upstream space, the volume of the upstream space and hence the volume of the vent chamber can be made as small as possible. There is an advantage.

Preferably, the ventilation chamber has a downstream space between the filter medium and the drift plate . If it does in this way, the contact area of the said gas in the said filter medium can be enlarged, and there exists an advantage that the removal efficiency of the mixture contained in the gas can be improved.

Preferably, the filter medium collects particles of 0.3 μm or more. In this way, there is an advantage that the volume of the ventilation chamber can be made as small as possible by applying a relatively thin filter medium .

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram illustrating a configuration of a gas analyzer 10 to which a gas analysis pretreatment device 16 according to an embodiment of the present invention is preferably applied. The gas analyzer 10 is preferably used for detecting the concentration of gas using exhaust gas as a sample in a compression combustion stroke of an internal combustion engine 12 such as a gasoline engine or a diesel engine, and is an internal combustion engine that is a measurement site. The sample gas discharged from the combustion chamber 14 of the engine 12 is introduced into the analysis cell 18 after being passed through the gas analysis pretreatment device 16 for removing the mixture contained in the sample gas. Yes.

  The analysis cell 18 includes an analysis unit 20 filled with a sample gas, an introduction port 22 through which the analysis unit 20 and the outlet 74 of the gas analysis pretreatment device 16 are conducted, and the analysis unit 20. And a discharge port 24 for discharging the sample gas filled therein. The analysis unit 20 is a space surrounded by a cell body 26 and a pair of glasses 28 that are brought into airtight contact with both ends of the cell body 26, and the pair of glasses 28 has an absorption wavelength of an analysis component. It is made of a material that has a relatively small attenuation in the band and suitably transmits infrared rays.

  On one side (incident side) of the analysis cell 18, there are a light source 30 that generates infrared light, and a first lens 32 that collects the infrared light generated by the light source 30 and makes it incident on the analysis unit 20. It is arranged. Further, on the other side (emission side) of the analysis cell 18, a light amount detection device 34 for detecting the light amount of a specific wavelength and the infrared light emitted from the analysis unit 20 are collected and the light amount detection device 34. A second lens 36 that is incident on the second lens 36 is disposed. The light quantity detection device 34 includes an optical filter 38 that transmits infrared light in a predetermined wavelength band, and an infrared sensor 40 that receives the infrared light transmitted by the optical filter 38 and detects the light quantity. Further, a disc 44 having a predetermined slit and a motor 46 for rotating the disc 44 around the axis are provided between the analysis cell 18 and the first lens 32. A chopper 42 for switching the transmission and blocking of the collected infrared rays at a predetermined time period and intermittently entering the infrared rays by entering the analysis unit 20 is provided.

  Around the analysis cell 18 and a pipe 50 for introducing a sample gas into the analysis cell 18, a heater 52 as a temperature control device is disposed. The analysis cell 18 is provided with a thermocouple 54 for detecting the temperature of the cell body 26. In response to a signal indicating the temperature of the cell body 26 supplied from the thermocouple 54, the temperature control circuit 56 turns on the heater 52 so as to keep the temperature of the cell body 26 and the analysis unit 20 constant.・ Control off.

  In the gas analyzer 10 configured as described above, the concentration of the sample gas filled in the analysis unit 30 is measured as follows. The sample gas discharged from the combustion chamber 14 due to the high pressure in the compression / combustion stroke of the internal combustion engine 12 is introduced into the gas analysis pretreatment device 16 via the pipe 48, and the gas analysis pretreatment device 16. After the mixture is removed, the analysis unit 20 of the analysis cell 18 is filled via the pipe 50. The infrared light generated by the light source 30 is collected by the first lens 32 and is incident on the analysis unit 20 of the analysis cell 18 through the chopper 42. Then, after passing through the analysis unit 20, it is emitted from the analysis cell 18, condensed by the second lens 36, and made incident on the light amount detection device 34. The concentration detection of the sample gas is performed by comparing the amount of infrared light generated by the light source 30 with the amount of infrared light detected by the light amount detector 34. That is, since gas molecules composed of two or more atoms have the property of absorbing infrared rays in a specific wavelength band, specific infrared rays generated by the light source 30 are allowed to pass through the analysis unit 20 to be specified. By detecting the attenuation of the amount of infrared light in the wavelength band, the concentration of the sample gas filled in the analysis unit 20 can be measured. The sample gas filled in the analysis unit 20 is discharged from the discharge port 24 to the atmosphere.

  FIG. 2 is a cross-sectional view for explaining the configuration of the gas analysis pretreatment apparatus 16, and the alternate long and short dash line arrow in the figure indicates the flow of the sample gas. In the gas analysis pretreatment device 16, a packing 62, a drift plate 64, a packing 66, a filter paper 68, and a mesh plate 70 are sandwiched between an upstream housing member 58 and a downstream housing member 60 constituting the housing from the upstream side. Has been configured. An inlet 72 formed in the upstream housing member 58 is connected to a pipe 48 for introducing a sample gas discharged from the combustion chamber 14 of the internal combustion engine 12, and an outlet 74 formed in the downstream housing member 60 is The sample gas after treatment is connected to a pipe 50 for supplying the analysis cell 18 to the analysis cell 18. Preferably, the inner diameters of the pipes 48 and 50 are equal, and the inlet 72 and the outlet 74 are both the same diameter. That is, the inlet 72 and the outlet 74 have the same cross-sectional area S1.

  Inside the gas analysis pretreatment device 16, a ventilation chamber is provided by the downstream surface of the upstream housing member 58, the inner peripheral surface of the downstream housing member 60, the inner peripheral surfaces of the packings 62 and 66, and the drift plate 64. (Ventilation space) 76 is formed, and the sample gas from the inlet 72 to the outlet 74 is allowed to pass through the ventilation chamber 76. The surface on the downstream side of the upstream housing member 58 is preferably a tapered surface that spreads in a conical shape with an apex angle θ1 being an obtuse angle from the inlet 72 toward the inner peripheral surface of the packing 62. The first space 78 that spreads in a conical shape having an obtuse angle θ1 from the upstream side to the downstream side by the surface, the inner peripheral surface of the packing 62, and the upstream surface of the drift plate 64 is the most upstream of the vent chamber 76. Formed on the side. Further, the second surface surrounded by the downstream surface of the drift plate 64 and the downstream surface of the drift plate 64 and the filter paper 68, the downstream surface of the drift plate 64, the inner peripheral surface of the packing 66, and the filter paper 68. A space 80 is formed. The first space 78 and the second space 80 respectively correspond to the upstream space and the downstream space that constitute the ventilation chamber 76. The downstream housing member 60 is preferably provided with a conical taper surface with an apex angle θ2 being an obtuse angle from the outlet 74 toward the mesh plate 70, and the taper surface causes the downstream side to flow downstream. A third space 82 is formed that extends in a conical shape with an apex angle θ2 being an obtuse angle toward the upstream side. The apex angle θ2 is preferably equal to or smaller than the apex angle θ1 of the first space 78.

  3A and 3B are views for explaining the drift plate 64, wherein FIG. 3A is a plan view viewed from the axial direction, and FIG. 3A, the drift plate 64 is provided with intermittent annular openings (slits) 84 penetrating in the thickness direction. The area S2 of the opening 84 is preferably larger than the cross-sectional area S1 of the inlet 72, and according to such a configuration, the flow path resistance in the ventilation chamber 76 is reduced. Moreover, as shown in FIG.3 (b), the taper surface 86 which spreads conically toward the upstream from the downstream is formed in the downstream. The packings 62 and 66 are annular members for sealing the space between the upstream housing member 58 and the downstream housing member 60 and forming the first space 78 and the second space 80. When the plate 64 is sandwiched between the upstream housing member 58 and the downstream housing member 60 via the packings 62 and 66, as shown by a one-dot chain line arrow in FIG. A flow path for guiding the gas flow to the peripheral edge of the cross section of the vent chamber 76 is formed. That is, the drift plate 64 corresponds to a drift element for suppressing the flow of the sample gas in the central portion of the cross section of the vent chamber 76.

  The filter paper 68 corresponds to a filtration element for collecting and removing the mixture contained in the sample gas that is allowed to pass through the ventilation chamber 76, and preferably 0.3 μm or more contained in the sample gas. It collects particles. The mesh plate 70 is a mesh member provided on the downstream side of the filter paper 68 for holding the filter paper 68 between the packing 66 and rectifying the sample gas discharged.

  In the gas analysis pretreatment apparatus 16 configured as described above, the sample gas supplied from the pipe 48 to the inlet 72 passes through the ventilation chamber 76 via a flow path as shown by a one-dot chain line arrow in FIG. And is quickly discharged from the outlet 74 to the pipe 50. In this process, the mixture that is not involved in the analysis by the gas analyzer 10 contained in the sample gas is removed by the filter paper 68.

  FIG. 4 is a diagram for explaining in detail the first space 78 and the second space 80 constituting the ventilation chamber 76, and FIG. 5 is a schematic diagram for explaining the cross-sectional area S 3 of the sample gas in the first space 78. FIG. A flow path cross-sectional area (surface area approximately perpendicular to the gas flow) S3 of the sample gas in the first space 78 shown in FIG. 5 corresponds to the diameter D of the tapered surface shown in FIG. Yes, preferably regardless of its diameter D, it is always larger than the cross-sectional area S1 of the inlet 72. That is, the apex angle θ1 shown in FIG. 4 is to make the flow path cross-sectional area S3 of the sample gas in the first space 78 larger than the cross-sectional area S1 of the inlet 72, and according to such a configuration, The flow path resistance in the ventilation chamber 76 becomes as small as possible.

  The flow area S3 of the sample gas in the first space 78 increases as the apex angle θ1 decreases, but the volume of the first space 78 also increases as the apex angle θ1 decreases. In order to improve the responsiveness of the gas analysis pretreatment device 16, the volume of the vent chamber 76 should be made as small as possible, and the apex angle θ1 is preferably a sample gas in the first space 78. The maximum cross-sectional area S3 is larger than the cross-sectional area S1 of the inlet 72.

  FIG. 6 shows a sample in the first space 78 corresponding to the diameter D when the diameter of the inlet 72 is 1 mm, the inner diameter (maximum diameter) of the ventilation chamber 76 is 10 mm, and the thickness dimension of the packing 62 is 0.05 mm. 4 is a graph showing a difference between a gas flow path area S3 and a cross-sectional area S1 of the inlet 72; Assuming that the flow path cross-sectional area S3 of the sample gas in the first space 78 is larger than the cross-sectional area S1 of the inlet 72, the apex angle θ1 is 178 ° and 176 °. In this case, in the vicinity of the inlet 72, the flow path cross-sectional area S3 of the sample gas in the first space 78 is smaller than the cross-sectional area S1 of the inlet 72 and does not satisfy the necessary conditions. On the other hand, when the apex angle θ1 is 174 ° and 172 °, irrespective of the diameter D, the flow path cross-sectional area S3 of the sample gas in the first space 78 is always larger than the cross-sectional area S1 of the inlet 72. Meet the requirements. Further, in order to make the volume of the first space 78 as small as possible, the maximum angle of the apex angles θ1 that satisfies the necessary condition should be adopted, and among the four angles shown in FIG. 174 ° is optimal. In such a manner, the sample gas in the first space 78 is calculated by calculating the maximum angle at which the cross-sectional area S3 of the sample gas in the first space 78 is larger than the cross-sectional area S1 of the inlet 72 for a finer angle. It is possible to set the apex angle θ1 that optimizes the distribution of.

  Thus, according to the present embodiment, the drift plate 64 that functions as a drift element for suppressing the flow of the sample gas in the central portion of the cross section of the vent chamber 76 is provided on the upstream side of the filter paper 68 that functions as a filter element. Therefore, the sample gas in the vent chamber 76 can be removed, and the filter paper 68 can efficiently remove the mixture contained in the sample gas. That is, the gas analysis pretreatment device 16 having excellent responsiveness can be provided.

  Further, since the drift plate 64 has an opening 84 for guiding the flow of the sample gas to the peripheral edge of the cross section of the vent chamber 76, the stagnation of the sample gas in the vent chamber 76 is more effectively performed. There is an advantage that it can be solved.

  Further, since the drift plate 64 has a tapered surface 86 that spreads out conically from the downstream side toward the upstream side, the sample gas flows along the tapered surface 86 so that the drifting plate 64 in the vent chamber 76 has its inside. In addition to being able to eliminate the sample gas stagnation more effectively, there is an advantage that the contact area of the sample gas in the filter paper 68 can be increased, and the removal efficiency of the mixture contained in the sample gas can be increased.

  Further, since the area S2 of the opening 84 of the drift plate 64 is larger than the cross-sectional area S1 of the inlet 72, high responsiveness is ensured without increasing the flow path resistance in the vent chamber 76. There is an advantage that you can.

  In addition, the ventilation chamber 76 has a first space 78 that is an upstream space that spreads in a conical shape having an obtuse angle θ1 from the inlet 72 toward the opening 84 of the drift plate 64. There is an advantage that the stagnation of the sample gas in the ventilation chamber 76 can be more effectively eliminated.

  Further, the apex angle θ1 increases the flow path resistance in the first space 78 because the cross-sectional area S3 of the sample gas in the first space 78 is larger than the cross-sectional area S1 of the inlet 72. There is an advantage that a high responsiveness can be ensured without making it.

  Further, the apex angle θ1 is the maximum angle that makes the cross-sectional area S3 of the sample gas in the first space 78 larger than the cross-sectional area S1 of the inlet 72, and thus the flow resistance in the first space 78. In addition to ensuring high responsiveness without increasing the volume, there is an advantage that the volume of the first space 78 and the volume of the vent chamber 76 can be reduced as much as possible.

  Further, since the ventilation chamber 76 has a second space 80 which is a downstream space between the filter paper 68 and the drift plate 64, the contact area of the sample gas in the filter paper 68 can be increased. There exists an advantage that the removal efficiency of the mixture contained in gas can be improved.

  Further, since the filter paper 68 collects particles of 0.3 μm or more, there is an advantage that the volume of the ventilation chamber 76 can be made as small as possible by applying a relatively thin filter paper 68. .

  The preferred embodiments of the present invention have been described in detail with reference to the drawings. However, the present invention is not limited to these embodiments, and may be implemented in other modes.

  FIG. 7 is a cross-sectional view illustrating a gas analysis pretreatment apparatus 90 including a drift plate 92 having a mode different from that of the above-described embodiment. As shown in FIG. 7, the drift plate 92 provided in the gas analysis pretreatment device 90 has a tapered surface 86 that spreads conically from the downstream side toward the upstream side, and also from the upstream side toward the downstream side. A second tapered surface 94 spreading in a conical shape may be provided on the upstream side of the tapered surface 86. In this way, the sample gas flowing along the second tapered surface 94 can more effectively eliminate the stagnation of the sample gas in the vent chamber 76, and the volume in the vent chamber 76 can be reduced. There is an advantage that responsiveness can be further enhanced.

  In the above-described embodiment, the gas analysis pretreatment device 16 includes the filter paper 68 as a filter element for removing the mixture contained in the sample gas. The filter medium may be provided as a filtering element.

  Further, the graph of FIG. 6 used for the description of the above-described embodiment is merely an example, and the optimum value of the apex angle θ1 is individually determined based on each parameter for each of the gas analysis pretreatment apparatuses having different configurations. Needless to say, it is calculated and set as follows.

  In the above-described embodiment, the gas analyzer 10 uses the exhaust gas in the compression combustion stroke of the internal combustion engine 12 as a sample gas, and a pump for pumping the gas at the measurement site is particularly provided. However, for example, a gas analyzer for measuring a gas component contained in the atmosphere is provided with a pump for feeding the gas at the measurement site into the gas analysis pretreatment device 16 and then into the analysis cell 18. It is done.

  In addition, although not illustrated one by one, the present invention is implemented with various modifications within a range not departing from the gist thereof.

It is a figure explaining the structure of the gas analyzer to which the gas analysis pre-processing apparatus which is one Example of this invention is applied suitably. It is sectional drawing explaining the structure of the gas analysis pretreatment apparatus of FIG. It is a figure explaining the drift plate with which the gas analysis pre-processing apparatus of FIG. 2 was equipped, (a) is the top view seen from the axial center direction, (b) is III-III sectional drawing of (a). It is a figure explaining the upstream space and downstream space which comprise the ventilation chamber in the gas analysis pretreatment apparatus of FIG. 2 in detail. It is a schematic diagram explaining the flow-path cross-sectional area of the sample gas in the upstream space of FIG. It is a graph which shows the difference of the flow-path area of sample gas in the upstream space in the gas analysis pre-processing apparatus of FIG. 2, and the cross-sectional area of an inlet_port | entrance. It is sectional drawing which illustrates the gas analysis pretreatment apparatus provided with the drift plate of the aspect different from the gas analysis pretreatment apparatus of FIG.

Explanation of symbols

16, 90: Gas analysis pretreatment device 58: Upstream housing member (housing)
60: Downstream housing member (housing)
64, 92: Drift plate (Drift element)
68: Filter paper (filtering element)
72: Inlet 74: Outlet 76: Ventilation chamber 78: First space (upstream space)
80: Second space (downstream space)
84: Opening 86: Tapered surface S1: Inlet cross-sectional area S2: Opening area S3: Channel cross-sectional area θ1: Vertical angle

Claims (7)

Includes a housing vent chamber gas toward said outlet is passed is formed from the inlet has a cross sectional area greater than the inlet and outlet, and a filter medium disposed in the vent chamber inside the housing, a gas analyzer pretreatment apparatus for removing the mixture contained in the gas by passing the filter medium prior to analysis of the gas,
Comprising a drift plate for suppressing flow of the gas in the center of the section of the vent chamber adjacent the upstream side of the filter medium, the said channeling plates, the flow of the gas to cross the peripheral portion of the vent chamber A gas analysis pretreatment apparatus, characterized in that an annular opening for guiding is provided penetrating in the thickness direction. The gas analysis pretreatment device according to claim 1, wherein the drift plate has a tapered surface that spreads conically from the downstream side toward the upstream side. The gas analysis pretreatment device according to claim 1 or 2, wherein an area of the opening of the drift plate is larger than a cross-sectional area of the inlet. The gas analysis pretreatment device according to any one of claims 1 to 3, wherein the ventilation chamber has an upstream space that spreads in a conical shape having an obtuse angle from the inlet toward the opening of the drift plate. .   The gas analysis pretreatment device according to claim 4, wherein the apex angle is such that a cross-sectional area of the gas in the upstream space is larger than a cross-sectional area of the inlet.   The gas analysis pretreatment device according to claim 4 or 5, wherein the apex angle is a maximum angle that makes a cross-sectional area of the gas flow path in the upstream space larger than a cross-sectional area of the inlet. The gas analysis pretreatment device according to any one of claims 1 to 6, wherein the ventilation chamber has a downstream space between the filter medium and the drift plate .

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