JP2003149099A - Apparatus for measuring engine exhaust gas - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus for measuring engine exhaust gases capable of performing desired measurements on the gases of an extremely low concentration level, by reliably purging all parts in contact with the gases including micro-gaps between component members of a sample line, micro-holes in the materials of the component members, etc. SOLUTION: The apparatus for measuring the engine exhaust gases is provided with the sample line 9 for introducing the gases G used for engine exhaust gas measurements to a gas analyzing part 39. The sample line 9 is provided with a line opening/closing means, and a vacuum pump 31 is connected to the sample line 9. Air is evacuated from the sample line 9 by the vacuum pump 31 to purge the sample line 9 by a vacuum.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an engine exhaust gas measuring device.

[0002]

BACKGROUND OF THE INVENTION As an engine exhaust gas measuring device, for example, the measurement of carbon monoxide (CO), total hydrocarbons (THC), nitrogen oxides (NO _x ) contained in exhaust gas emitted from an automobile engine is performed. There is something to do.

In the above-mentioned engine exhaust gas measuring apparatus, in order to clean the sample line for introducing the exhaust gas as a sample gas into the gas analysis section, conventionally, as shown in FIG. A large amount of clean purge gas P is supplied to the sample line 72 provided on the upstream side of the gas analysis unit 71 in a pressurized state to remove the residue attached to or remaining on each part in the sample line 72. Was doing.

[0004]

However, the sample line is provided with a large number of various members such as a solenoid valve, a pump, a flow meter, and a regulator, and a portion of these members that comes into contact with gas (gas contact portion). It is difficult to allow the purge gas P to flow through all of them, and the purging of intricate parts, minute gaps of component parts such as solenoid valves, minute holes of material of the component parts, etc. can be performed only in an insufficient state. could not. Further, in the engine exhaust gas measuring device having a complicated sample line, a solenoid valve for flowing the purge gas P and a control unit for controlling them are required in each line, which further complicates the internal structure of the device.

Further, in the case of insufficient purging as described above, the residue in each part of the sample line 72 becomes a background in exhaust gas measurement, which makes gas measurement at an extremely low concentration level difficult. Furthermore, the consumption of a large amount of purge gas P raises the running cost, and the complicated device lowers the assembling property and the maintainability, and causes the cost increase.

The present invention has been made in view of the above matters, and an object thereof is to ensure all gas contact parts including minute gaps in the constituent members of the sample line and minute holes in the material of the constituent members. It is an object of the present invention to provide an engine exhaust gas measuring device capable of performing desired purging even in gas measurement at an extremely low concentration level by enabling the purging of the engine.

[0007]

In order to achieve the above object, the present invention provides an engine exhaust gas measuring device equipped with a sample line for introducing a gas used for engine exhaust gas measurement into a gas analysis section, While a line opening / closing means is provided in the sample line, a vacuum pump is connected to the sample line, and the sample line is evacuated by the vacuum pump to perform vacuum purging of the sample line (claim 1).

Further, according to the present invention, in the engine exhaust gas measuring device provided with a sample line for introducing the gas used for measuring the engine exhaust gas into the gas analysis section, while the line opening / closing means is provided in the sample line, the sample line A vacuum pump is connected to, and a purge gas line equipped with means for adjusting the flow rate of the purge gas to be introduced is connected to the sample line, and the sample line is introduced by the vacuum pump while introducing the purge gas through the flow rate adjusting means. The sample line is vacuum-purged by vacuuming at an arbitrary negative pressure (claim 2).

The gas used for the engine measurement means the exhaust gas of the engine, the air for diluting the exhaust gas, or the diluted exhaust gas, and the sample line means the sampling line for the dilution air, The sample gas line connected to the pipe through which the diluted exhaust gas flows, the sample gas line for introducing the exhaust gas into the gas analysis unit, and the like.

In any of the above engine exhaust gas measuring devices, the sample line may be heated when performing vacuum purging (claim 3).

In the above engine exhaust gas measuring device,
Since the sample line is evacuated by the vacuum pump to make the sample line negative pressure, the residue is removed from all the gas contact parts that have become negative pressure, and the part including all the gas contact parts in the sample line is removed. It is surely purged. Also,
By introducing the purge gas and adjusting the negative pressure state as in the second aspect, the purge can be performed more efficiently. That is, in vacuum purging, the cleaning effect can be expected in a shorter time as the internal pressure of the sample line is lower. However, an excessively low internal pressure leads to mixing of outside air (leakage from the outside), which may lead to contamination of the sample line. On the other hand, in order to secure higher airtightness and pressure resistance, naturally, expensive components are required, which leads to an increase in the cost of the entire device. Here, in the vacuum purge in which the purge gas is introduced, the above-described cleaning effect and airtightness are balanced by introducing the purge gas. Therefore, the flow rate of the purge gas is determined in consideration of these balances.

[0012]

DETAILED DESCRIPTION OF THE INVENTION The details of the present invention will be described below with reference to the drawings. FIG. 1 shows an example of the engine exhaust gas measuring apparatus of the present invention, and in this embodiment,
In particular, the exhaust gas from the engine is diluted with diluted air, and a part of this diluted exhaust gas is stored in a sample bag.
(nstant Volume Sampler) is shown.

In FIG. 1, reference numeral 1 denotes a pipe through which the diluted exhaust gas G flows, and an inlet pipe 2 for introducing the exhaust gas G from an engine (not shown) and a dilution air A at its upstream end.
A diluting air introducing pipe 3 for introducing is connected. A main venturi 4 for sucking at a constant flow rate is provided in the middle of the pipe 1, and its downstream side is connected to a turbo blower (not shown). Pipes 1 and 5
The pressure sensor and the temperature sensor are provided on the upstream side of the main venturi 4. Further, 7 is a filter provided at the upstream end of the air introducing pipe 3.

Reference numeral 8 is a sampling venturi for sampling a part of the diluted exhaust gas G flowing through the pipe 1, and a sample gas line (an example of a sample line) 9 on the downstream side of which the sampled diluted exhaust gas G flows.
Are connected. A plurality of (three in the illustrated example) sample bags 11a to 11c are connected to the sample gas line 9 via an electromagnetic valve unit 10 including a plurality of (nine in the illustrated example) electromagnetic valves 10a to 10i. There is. And the sampling venturi 8 of the sample gas line 9
From the upstream side to the solenoid valve unit 10, a solenoid valve 12 as a line opening / closing means, a flow meter 13,
A filter 14 and a suction pump 15 for sampling are provided, and the solenoid valve 12 is connected to the sample bag 11a.
The sample gas line 9, the filter 14, and the solenoid valve unit 10 up to 11c are configured to be temperature-controlled by a heater or the like. 16 to 18 are controllers for adjusting the temperature.

A purge gas line 19 is connected upstream of the sample gas line 9 and in parallel with the sampling venturi 8. From the upstream side, a gas inlet 20, a regulator 21, a pressure gauge 22, and a flow rate adjustment are provided. Means 2
3. A solenoid valve 24 is provided, and the downstream side of the solenoid valve 24 is connected at a point 25 on the downstream side of the solenoid valve 12 of the sample gas line 9, and, for example, nitrogen gas or air as a clean purge gas P is introduced. It is configured to be able to. The flow rate adjusting means 23 is composed of, for example, a needle valve 26 and an electromagnetic valve 27 connected in series, and a capillary 28 connected in parallel.

Further, 29 is a vacuum evacuation line provided downstream of the sample gas line 9 via the electromagnetic valve unit 10, and an electromagnetic valve 30 and a vacuum pump 31 are connected in series to the evacuation line 29. The vacuum pump 31 is open to the atmosphere on the downstream side. Further, 32 is a vacuum gauge for detecting the vacuum state of the evacuation line 29.

Further, 33 is a sampling line for the dilution air A, the upstream side of which is connected to the dilution air introduction pipe 3. On the downstream side of the dilution air sampling line 33, a plurality (nine in the illustrated example) of solenoid valves 34a to.
A plurality of (three in the illustrated example) sample bags 35a to 35c are provided via an electromagnetic valve unit 34 composed of 34i. And the dilution air sampling line 33
From the upstream side to the upstream side of the solenoid valve unit 34 of
A sampling suction pump 38 that operates in conjunction with the flow meter 36, the needle valve 37, and the suction pump 15 is provided.

Although not shown in detail, 39 is a gas analysis unit. In this gas analysis unit 39, for example, a plurality of gas analyzers are provided so that CO, THC, NO _x, etc. can be measured, respectively. Is provided. Then, in the gas analysis unit 39, the diluted exhaust gas G in the sample bags 11a to 11c and the sample bags 35a to 35c.
The dilution air A inside is supplied as a sample gas, and in the illustrated example, the diluted exhaust gas G flowing through the pipe 1 and the dilution air A flowing through the dilution air introducing pipe 3 are directly supplied. There is.

That is, in FIG. 1, 40 is a sample gas line provided independently of the sample gas line 9, and its upstream side is connected to the pipe 1 via a sample probe 41. The sample probe 41 is, for example, inserted and connected to the pipe 1 on the downstream side of the sampling venturi 8 of the sample gas line 9 and on the upstream side of the main venturi 4, and the downstream side is connected to the gas analyzer 39 via the three-way solenoid valve 42. It is connected. Three-way solenoid valve 42
Is connected to a dilution air sampling line 43 branched from the dilution air sampling line 33,
By switching the three-way solenoid valve 42, either the diluted exhaust gas G flowing through the pipe 1 or the dilution air A flowing through the dilution air introduction pipe 3 is selected to select the gas analysis unit 3
It is configured so that it can be introduced in 9. The connection position of the sample probe 41 to the pipe 1 is not limited to the above.

Reference numeral 44 denotes sample bags 11a to 11c, 3
A gas supply line from 5a to 35c to the gas analysis unit 39, the upstream side of which is connected to the solenoid valve units 10 and 34, and includes a needle valve 45, a suction pump 46, and a solenoid valve 47 as a line opening / closing means. There is. Also, 48
Is another purge gas line for introducing a purge gas (for example, clean nitrogen gas or air) P into the sample bags 11a to 11c and 35a to 35c. From the upstream side thereof, a pressure regulating valve 49, a pressure gauge 50, and a line opening / closing means. Solenoid valve 51 is provided, and its downstream side is connected to the vacuuming line 29.
0,34. Reference numeral 53 is a vacuum switch provided in the purge gas line 48.

Next, an example of the purging procedure in the engine exhaust gas measuring apparatus having the above-mentioned structure will be described. (1) First, the solenoid valve 12 located on the most upstream side of the sample gas line 9, the solenoid valves 47 and 51 on the downstream side, and the solenoid valves 34d to 34i of the solenoid valve unit 34 are closed to be in a state of being shut off from the outside. . Then, the solenoid valves 27 and 24 of the purge gas line 19, all the solenoid valves 10a to 10i of the solenoid valve unit 10, and the solenoid valve 30 of the vacuum evacuation line 29.
Open all of. In this state, the vacuum pump 31 of the evacuation line 29 is operated. As a result, a large amount of purge gas P is introduced into the purge gas line 19, the purge gas P is supplied to the sample gas line 9 through the needle valve 26 and the electromagnetic valves 27 and 24, and the purge gas P causes the inside of the sample gas line 9 to flow. Is scavenged. This scavenging time is set arbitrarily.

(2) Next, after completion of the scavenging, the solenoid valve 27 is closed. As a result, the purge gas P is supplied to the sample gas line 9 via the capillary 28 and the solenoid valve 24. In this case, the flow rate of the purge gas P to the sample gas line 9 is regulated by the capillary 28 and is extremely small. The inside of the sample gas line 9 is, so to speak, shut off from the outside, and the vacuum is evacuated by the vacuum pump 31 on the downstream side thereof, so that the inside is in a negative pressure state and vacuum purged. Therefore, the purge gas P introduced into the sample gas line 9 is discharged to the outside via the flow meter 13, the filter 14, the sampling pump 15, the electromagnetic valve unit 10, and the vacuum pump 31. In particular, the sampling pump 15
Since the exhaust gas G of high pressure flows from the line to the solenoid valve unit 10, it is extremely easy to get dirty.
As the purge gas P flows, it is surely cleaned. Further, the pressure in the sample gas line 9 is adjusted by the regulator 21 and the capillary 28 according to the airtightness of the device, and the inside of the sample gas line 9 is prevented from being contaminated by the invasion of the outside air due to the leak. The flow rate of the purge gas P is, for example, 500 mL / min, and the vacuum purge time is set to about 8 hours.

When performing the vacuum purging, the heater may be operated to heat the sample gas line 9 at a predetermined temperature. In this case, the adsorbed substances such as THC having a high boiling point are removed. And the time required for vacuum purging can be shortened. When the sample gas line 9 is heated with a predetermined temperature during the vacuum purge, the heater is turned off at the end of the purge and a cooling fan (not shown) provided near the sample gas line 9 is provided. ) Is preferably operated to cool the heated portion.

When the solenoid valve 27 is opened after completion of the vacuum purge, a large amount of purge gas P is introduced in the purge gas line 19.
Is introduced, and the inside of the sample gas line 9 is filled with this, so that the pressure in the sample gas line 9 is recovered, and the sample gas line 9 is prevented from being contaminated by the invasion of the outside air due to the leak. After that, all solenoid valves 27, 24, 1
0a to 10i and 30 are closed, and purging is completed.

As described above, in the engine exhaust gas measuring apparatus of the present invention, the sample gas line 9 is evacuated by the vacuum pump 31 and the sample gas line 9 is made to have a negative pressure. The residue is removed from all of the portions, and the fine portion including all the gas contacting portions in the sample gas line 9 is reliably purged. Further, by introducing a small amount of the purge gas P and adjusting the pressure, it is possible to more efficiently perform the purging of the sample gas line 9 whose airtightness cannot be sufficiently maintained.

That is, in the above engine exhaust gas measuring apparatus, when the sample gas line 9 is purged, the minute spaces of various components such as the solenoid valve provided in the sample gas line 9 and the minute spaces in the parts forming them are small. Vacuum purging is performed so that all gas contact parts, such as holes and gas reservoirs, are in a substantially negative pressure state, so all the minute foreign matter adsorbed on the minute parts are uniformly removed and discharged. It Moreover, since a small amount of the purge gas P is made to flow through the sample gas line 9 during the vacuum purge, the most contaminated part in the sample gas line 9 can be surely cleaned. During the vacuum purging, the sample gas line 9 is adjusted to an appropriate pressure according to the airtightness of the apparatus, so that the sample gas line 9 is prevented from entering the sample gas line 9 due to a leak, and the sample gas line 9 is prevented from leaking. Contamination is prevented.

Therefore, in the engine exhaust gas measuring apparatus that is purged as described above, the background in exhaust gas measurement is almost eliminated, so that exhaust gas measurement at a level such as extremely low concentration can be accurately performed.

In the engine exhaust gas measuring device, the amount of purge gas P consumed is extremely small, and the cost required for maintenance is reduced. Further, when the line is complicated and the same purging effect is required, the structure of the entire apparatus is simplified, so that the assemblability and the maintainability are improved, and the cost can be reduced.

In the above embodiment, a small amount of purge gas P is caused to flow when the vacuum pump 31 evacuates, but only the vacuum may be evacuated. Even in this case, the fine portion can be sufficiently cleaned.

Further, in the above embodiment, as the flow rate adjusting means 23, the one in which the electromagnetic valve 27 and the capillary 28 are connected in parallel is used, but instead of this, a flow rate control valve such as a mass flow controller is used. Can also be used.

By the way, in the above embodiment,
Although the sample gas line 9 connected to the pipe 1 and the purging of the respective parts provided therein have been described,
The present invention is not limited to this, and the dilution air A
Of the sample gas line 9 to the sampling line 33 of
The same purging as described above may be performed to perform the same purging as described above. However, for the sampling line 33 of the dilution air A, the sample gas line 9
The sample gas line 40 to the gas analysis section 39 is not so dirty and the sample gas line 9
Since the structure is not so complicated, the necessity of performing the purging seems to be lower than that of the sample gas line 9.

That is, as understood from the above description, when the diluted exhaust gas G is sampled using the constant volume sampling device and stored in the sample bags 11a to 11c, an electromagnetic valve or a sample gas line 9 is provided. A large number of various components such as sample bags are used. Therefore, in such an engine exhaust gas measuring device, although the present invention exhibits particularly useful effects,
It goes without saying that a useful effect is exhibited even when the bag sampling is not performed.

[0033]

As described above, according to the present invention, it is possible to reliably purge all the gas contact portions including the minute gaps in the constituent members of the sample line and the minute holes in the material of the constituent members. Therefore, it is possible to obtain an engine exhaust gas measurement device that can perform desired measurement even in gas measurement at an extremely low concentration level.

[Brief description of drawings]

FIG. 1 is a diagram schematically showing an example of the configuration of an engine exhaust gas measuring apparatus of the present invention.

FIG. 2 is a diagram for explaining a conventional technique.

[Explanation of symbols]

9 ... Sample line, 12 ... Electromagnetic valve, 19 ... Purge gas line, 23 ... Flow rate adjusting means, 31 ... Vacuum pump, 39
... gas analysis part, 47 ... solenoid valve, 51 ... solenoid valve, A ... dilution air, G ... exhaust gas, P ... purge gas.

Continued front page    (72) Inventor Hiroshi Kawabe             2 Higashimachi, Kichijoin-miya, Minami-ku, Kyoto-shi, Kyoto             HORIBA, Ltd. F-term (reference) 2G052 AA02 AB02 AB05 AB07 AB12                       AD42 BA14 CA11 CA38 EB11                       HC28 JA03

Claims (3)

[Claims] 1. An engine exhaust gas measuring apparatus having a sample line for introducing a gas used for measuring engine exhaust gas into a gas analysis section, wherein a line opening / closing means is provided in the sample line and a vacuum pump is provided in the sample line. An engine exhaust gas measuring apparatus, which is connected, and vacuumed the sample line by this vacuum pump to perform vacuum purging of the sample line. 2. An engine exhaust gas measuring apparatus provided with a sample line for introducing a gas used for measuring engine exhaust gas into a gas analysis section, wherein a line opening / closing means is provided in the sample line and a vacuum pump is provided in the sample line. A purge gas line having a means for adjusting the flow rate of the purge gas to be introduced is connected to the sample line, and the vacuum pump pumps the sample line at an arbitrary negative pressure while introducing the purge gas through the flow rate adjusting means. An engine exhaust gas measuring apparatus, characterized in that a vacuum is drawn to perform vacuum purging of the sample line. 3. The engine exhaust gas measuring apparatus according to claim 1, wherein the sample line is heated when vacuum purging is performed.