JPH08122230A - Multipoint sample measuring device - Google Patents

Abstract

PURPOSE: To eliminate response delay after measuring point is switched without separately preparing reference gas by alternately dividing sample pipes into two groups in the measuring order, and arranging the same side by side to be taken as first and second sampling lines. CONSTITUTION: At the time of measurement by a sample pipe 1, electromagnetic switching valves 81, 82 are turned on, a solenoid three-way valve 13 is turned on, and a solenoid three-way valve 16 is turned off to introduce gas in the sampling pipe 1 into a sampling line 21 and introduce gas in a sample pipe 2 into a sampling line 22. Gas from the line 21 is taken as measuring gas, and gas from the line 22 is taken as reference gas through a converter to be introduced into an analyzer 20. At the time of measurement by a sample pipe 2, the electromagnetic switching valves 82, 83 and the three-way solenoid valves 13, 16 are operated to introduce gas in a sample pipe 3 into the line 21, introduce gas in the sample pipe 2 into the line 22, introduce gas in the line 21 into a reference gas line 36, and introduce gas in the line 22 into the analyzer through a measuring gas line 35. Hereinafter, multipoint switching measurement can be sequentially made by switching the respective valves.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multipoint sample measuring device used for measuring CO concentration in the atmosphere at a plurality of measuring points.

[0002]

2. Description of the Related Art When conducting an exhaust gas test of an automobile engine, a multi-point sample measuring device is used to monitor and measure the CO concentration in each measuring chamber concerned.
In addition, specified gas (CO or CH ₄ ) is used at several places in the general factory.
The same applies to the case of measuring. In the multipoint sample measuring device, as shown in FIG. 3, for example, sampling pumps P1 to P6 are conventionally provided for each sampling line S1 to S6.
Is often provided, and each sampling pump is activated for each measurement of each sampling line.

When a fluid modulation type analyzer or a sample switching type analyzer is used as a CO analyzer, it is common to purify the atmosphere around the analyzer and use it as a reference gas. It requires a dedicated purification line.

[0004]

Therefore, in the conventional multi-point sample measuring apparatus, the number of sampling pumps increases as the number of measuring points increases, and a dedicated reference gas refining process line is also required, resulting in an increase in size of the apparatus. However, there was a drawback that the cost was high.

Moreover, since the sampling pump of each measurement line is activated when the sampling line is switched, there is a problem that the introduction of the sample gas into the analyzer is delayed and the response is delayed.

The present invention has been made in view of such circumstances.
It is an object of the present invention to provide a compact and inexpensive multi-point sample measuring device capable of eliminating a response delay after switching measurement points without separately preparing a reference gas.

[0007]

The present invention has means for solving the above-mentioned problems as follows. That is, a plurality of sample tubes each having a filter and an on-off valve are arranged in parallel, and the respective sample tubes merge and are connected to a first sampling line, and the first sampling line has a first sampling pump. And the first
While a three-way valve is provided, a plurality of sample tubes each having a filter and an on-off valve are arranged in parallel, and the respective sample tubes merge and are connected to a second sampling line, and the second sampling line is connected to the second sampling line. A second sampling pump and a second three-way valve are provided, and the first
The sampling line is branched and connected to the first branch line and the second branch line via the first three-way valve, respectively, while the second sampling line is connected to the third branch line and the fourth branch line via the second three-way valve. Branched to a branch line,
In addition, the first branch line and the third branch line are joined and connected to the measurement gas line, and the measurement gas line is introduced and connected to the analyzer, and the second branch line and the fourth branch line are connected to the converter. It is characterized in that the reference gas line is joined and connected to the reference gas line, and the reference gas line is introduced and connected to the analyzer.

[0008]

When the measurement of the CO component in the atmosphere is described as an example (see FIG. 1), the on-off valves 81 and 82 are turned on and the gas of the sample tube 1 is supplied to the first sampling line 21 when measuring with the sample tube 1. Also, the gas of the sample tube 2 is introduced into the second sampling line 22, the gas from the first sampling line 21 is introduced into the analyzer 20 as a measurement gas, and the gas from the second sampling line 22 is converted. It is introduced into the analyzer 20 via 17 as a reference gas.

Next, at the time of measurement with the sample tube 2,
The on-off valves 82 and 83 are turned on, the gas of the sample tube 3 is introduced into the first sampling line 21, and the gas of the sample tube 2 is introduced into the second sampling line 22.
The three-way valves 13 and 16 are switched to introduce the gas in the first sampling line 21 into the reference gas line 36 and the gas in the second sampling line 22 into the analyzer 20 via the measurement gas line 35.

Thereafter, similarly, the switching multipoint measurement can be sequentially performed on the sample tubes 3 to 6.

[0011]

Embodiments of the multipoint sample measuring apparatus of the present invention will be described below in detail with reference to the drawings. FIG. 1 shows the configuration of an apparatus using a fluid modulation type analyzer 20. Reference numerals 1 to 6 are sample tubes, 7 is a filter, 8 (81 to 86) is a normally closed electromagnetic on-off valve (on-off valve), and 21 is A first sampling line to which the sample tubes 1, 3, 5 are joined together,
22 is a second sampling line to which the sample tubes 2, 4 and 6 are joined together, 11 is a first sampling pump, 14
Is a second sampling pump, 12 is a first pressure regulating valve, 1
Reference numeral 5 is a second pressure regulating valve, 13 is a first electromagnetic three-way valve (first three-way valve), and 16 is a second electromagnetic three-way valve (second three-way valve).

Reference numeral 31 is a first branch line connected to the first sampling line 21 via the first electromagnetic three-way valve 13 in a normally open manner. Reference numeral 32 is normally closed to the first sampling line 21 via the first electromagnetic three-way valve 13. Is connected to the second sampling line 22 via the second electromagnetic three-way valve 16, and the third branch line is connected to the second sampling line 22 in a normally closed state. Reference numeral 34 is second via the second electromagnetic three-way valve 16. It is a fourth branch line that is connected to the sampling line 22 in a normally open manner.

Reference numeral 35 is a measurement gas line in which the first branch line 31 and the third branch line 33 are joined together, and 36 is a second gas line.
A reference gas line 17 in which the branch line 32 and the fourth branch line 34 are joined and connected is a converter, and a measurement gas line 35 and a reference gas line 36 thereof are introduced and connected to the fluid modulation type analyzer 20. In addition, B1-B4 each show a junction connection point.

With the apparatus having such a configuration, it is possible to successively perform CO multi-point analysis measurement with good responsiveness in the following manner (see FIG. 2). When measuring with the sample tube 1, the electromagnetic on-off valves 81 and 82 are turned on, the first electromagnetic three-way valve 13 is turned on, the second electromagnetic three-way valve 16 is turned off, and the gas of the sample tube 1 is supplied to the first sampling line 21. , And the sample tube 2 on the second sampling line 22.
Gas is introduced into the analyzer 20 as the measurement gas, and the gas from the second sampling line 22 is introduced into the analyzer 20 as the reference gas via the converter 17. To do.

Next, at the time of measurement with the sample tube 2,
When the electromagnetic opening / closing valves 82 and 83 are turned on, the first electromagnetic three-way valve 13 is turned off, and the second electromagnetic three-way valve 16 is turned on, the first
The gas of the sample tube 3 is introduced into the sampling line 21, the gas of the sample tube 2 is introduced into the second sampling line 22, and the gas of the first sampling line 21 is introduced into the reference gas line 36 and the second sampling line. The gas in line 22 is introduced into analyzer 20 via measurement gas line 35. Similarly, the multipoint switching measurement can be sequentially performed by switching the electromagnetic opening / closing valve 8 and the first and second electromagnetic three-way valves 13 and 16.

As described above, at the time of switching the measurement point, the sample gas is introduced from the sample tube for starting the measurement and used as the reference gas. It becomes possible to measure. Further, there is an advantage that it is not necessary to separately prepare a reference gas, and moisture interference correction can be simultaneously performed. A dehumidifier may be provided in front of the analyzer 20 in order to improve the measurement accuracy.

As described above, in addition to the need for a separate refining device or supply device for the reference gas, only two sampling pumps 11 and 14 are required for the six sample tubes 1 to 6. Therefore, it is possible to effectively realize downsizing of the device and cost reduction.
Further, it is possible to use a minimum number of solenoid valves and the minimum power consumption.

The number of sample tubes arranged in parallel may be set appropriately, and the object to be measured is not limited to CO. For example, CO ₂ , NO, NO ₂ , HC
And SO ₂ can also be measured.

[0019]

As described above, according to the multipoint sample measuring apparatus of the present invention, the sample tube is divided into two parts in the order of measurement and arranged in parallel, and one of them is arranged in the first sampling line. , The other is used as the second sampling line, and when measuring the gas from the first sampling line, the gas from the second sampling line is used as the reference gas, so that the response delay after the switching of the measurement points can be eliminated. Further, it is not necessary to prepare the reference gas, and only two sampling pumps are required, and the device can be made compact and the cost can be reduced. In addition, it can be implemented with the minimum number of parts and the minimum power consumption.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of a multipoint sample measuring device of the present invention.

FIG. 2 is the same time chart.

FIG. 3 is a configuration diagram showing an example of a conventional multipoint sample measuring device.

[Explanation of symbols]

1 to 6 ... sample tube, 21 ... first sampling line,
22 ... 2nd sampling line, 7 ... Filter, 8 (8
1-86) ... on-off valve, 11 ... first sampling pump,
13 ... 1st three-way valve, 14 ... 2nd sampling pump, 1
6 ... Second three-way valve, 17 ... Converter, 20 ... Analyzer, 3
1 ... 1st branch line, 32 ... 2nd branch line, 33 ... 3rd branch line, 34 ... 4th branch line, 35 ... Measurement gas line, 36 ... Reference gas line.

Claims (1)

[Claims] 1. A plurality of sample tubes each having a filter and an on-off valve are arranged in parallel, and the respective sample tubes are joined together and connected to a first sampling line, and the first sampling line has a first sampling line. While one sampling pump and a first three-way valve are provided, a plurality of sample tubes each having a filter and an on-off valve are arranged in parallel,
Further, the respective sample tubes are joined and connected to the second sampling line, and the second sampling line is provided with a second sampling pump and a second three-way valve, and
The first sampling line is branched and connected to the first branch line and the second branch line via the first three-way valve, respectively, while the second sampling line is connected to the third branch line via the second three-way valve. And the fourth branch line, and the first branch line and the third branch line are joined together to the measurement gas line to introduce and connect the measurement gas line to the analyzer, and the second branch line. And a fourth branch line are joined to a reference gas line having a converter, and the reference gas line is introduced and connected to the analyzer.