JPH0419540A - Automatic gas analyzing apparatus - Google Patents

Abstract

PURPOSE:To allow the automatic parallel analyses of plural gaseous components by installing a pressure gauge to a measuring pipe, communicating an auxiliary chamber which is opened in the upper part to absorption vessels and connecting the upper part of the vessels and a multiway cock with the capillary built in a liquid level gage. CONSTITUTION:A gaseous sample introducing pipe 1, a gas suction discharge part 6, the absorption vessels 8c, 9c, a discharge pipe 10 and the 6-way cock 5 are directly connected. After the prescribed prepn. for measurement is made, the following operations are successively performed by the rotation of the cock 5: The introducing pipe 1 and the discharge pipe 10 are first connected and the gaseous sample is run. The introducing pipe 1 and the measuring pipe 6a are then connected to suck a prescribed amt. of the gaseous sample and the gaseous pressure is measured. The measuring pipe 6a and the vessel 8c are connected to absorb the carbon dioxide and gaseous oxygen into the an absorption liquid 8e and the gaseous volume and pressure in the measuring pipe 6a are measured. The amt. of the gas absorbed corresponding to the amt. of the carbon dioxide and gaseous oxygen is calculated from the respective measured values. The plural gaseous components are automatically analyzed in parallel under the same conditions in this way.

Description

Detailed Description of the Invention (Industrial Application Field) The present invention provides an automatic gas analyzer suitable for measuring carbon dioxide and oxygen concentrations contained in gas discharged from combustion equipment such as boilers and diesel engines. Regarding.

(Conventional technology) The concentration of carbon dioxide and oxygen contained in combustion exhaust gas is determined by
This is an essential measurement item for calculating the efficiency of diesel engines and converting nitrogen oxide concentrations. Conventionally, electrical measurement methods using magnetism, zirconia, non-dispersive infrared rays, etc., and Orsat gas analysis methods have been used to analyze this gas. Only one of these can be measured, and the electrical measurement method must be calibrated using an Orzanoto gas analyzer, so the Orzanoto gas analyzer is often used for the above concentration measurements.

(Problem to be solved by the invention) However, in the Orsat type gas analyzer, in order to collect the sample gas into the gas villet, it is necessary to align the liquid level of the sealing liquid with the zero scale of the gas villet, and to collect the gas remaining in the absorption bottle. The work of aligning the liquid level of the absorption liquid with the marked line of the absorption bottle when transferring it to the gas bure/nod is an important process that affects the accuracy of gas analysis, but this work is complicated and lengthens the analysis time. It was the cause. In addition, during the above work, the sealing liquid and absorption liquid may be washed away due to slight carelessness.
Sometimes I made the mistake of having to clean the analyzer.

The present invention aims to eliminate the above-mentioned drawbacks and provide a gas analyzer that can automatically analyze a plurality of gas components in parallel.

(Means for Solving the Problems) The present invention provides a sample gas introduction pipe, a gas discharge pipe, a measuring pipe for driving a piston with a stepping motor, and an absorption device that accommodates different absorption liquids corresponding to sample gas components. An automatic gas analyzer that connects a and a multi-directional hook,
A pressure gauge is attached to the measuring tube, and the auxiliary chamber, which is open at the top, is communicated with the absorption container of the gas absorption device, and the upper part of the absorption container and the multi-way joint are connected by a thin tube containing a liquid level gauge. This is an automatic gas analyzer characterized by being connected to enable parallel analysis of multiple gas components.

(Function) The present invention measures the gas from the sample gas introduction section under the same conditions by directly connecting a plurality of gas absorption devices and one measuring device to a multi-way cock, and directly connects the gas absorption device to the gas absorption device via the cock. By operating one cock, a plurality of gas components can be sequentially supplied to each gas absorption device and analyzed in parallel.

(Example) FIG. 1 is a flow diagram of an automatic gas analyzer that is an example of the present invention.

This analyzer includes a sample gas inlet pipe 1, a gas suction/discharge section 6 having a measuring tube 6a, two absorption containers 8c and 9c, and a discharge pipe IO directly connected to a hexagonal cock 5. The conduit connecting the absorption container and the like is all made of a material that has low gas adsorption (eg, tetrafluoroethylene resin). The sample gas introduction tube 1 is equipped with a filter 2 for removing soot, oil mist, etc. contained in the sample gas.
, a plastic trap 3 that stores water and a diaphragm type suction pump 4 for adjusting the water concentration to a constant level, and are connected to a six-way cock 5.

The hexagonal cock 5 switches between three pairs of flow paths and is connected to a drive motor 5a. The measuring tube 6a has a syringe-like shape, the outer tube and the piston 6c are processed to be highly airtight, and has an internal volume of approximately IO to 1,001. The piston 6c is a feed rod 7b with a spiral convex groove formed on its outer peripheral surface.
The upper part is vertically attached to the branch 7d of the outer frame 7c. On the other hand, the inner frame 7e is provided with a bearing 7r having a groove formed on its inner circumferential surface, and the gear on the upper part of the bearing 7r is connected to the gear of the stepping motor 7a via a timing belt 7g. That is, the rotation of the stepping motor 7a is transmitted to the bearing 7r by the timing bell 7g, and the rotation of the feed rod 7b moves the piston 6C up and down.

A pressure gauge 6b for measuring the pressure in the space between the outer cylinder and the inner cylinder is attached to the measuring tube 6a.

A certain amount of sample gas measured by the metering tube 6a is introduced into the absorption sections 8 and 9 through the hexagonal cock 5.

The absorption containers 8c and 9c are made of transparent material.
Sub-chambers 8d and 9d are provided which communicate with each other at the bottom.

The absorption containers 8c and 9c are placed on rotators 8g and 9g, and a magnet is attached to a small motor inside the rotator, and the rotation of the motor causes the rotors 8f and 9 in the absorption containers to be rotated.
Rotate f. In the absorption container 8c, there is a mixed aqueous solution 8 of potassium hydroxide and pyrogallol for absorbing oxygen gas.
The absorption container 9c contains an aqueous potassium hydroxide solution 9e for absorbing carbon dioxide gas.

Platinum wires 8b, 9b are embedded in the upper portions of the absorption containers 8c, 9c for detecting the liquid levels of the mixed aqueous solution 8e and the potassium hydroxide aqueous solution 9e. Platinum wire 8a, 9a
is arranged in a thin tube connected to the upper part of the absorption containers 8c, 9c.

The control device 11 is for performing sequential control within the flow path, and the main control contents are introduction of sample gas, metering, driving of the suction pump, etc., and the pressure of the pressure gauge 6b is digitized. After the calculation, it is printed and recorded on the printer 12.

Next, the measurement procedure will be explained.

■) An absorption liquid 8e consisting of a mixed aqueous solution of potassium hydroxide and pyrogallol corresponding to the carbon dioxide and oxygen gas components of the sample gas is stored in a gas absorption container 8C, and an absorption liquid 9e consisting of an aqueous potassium hydroxide solution corresponding to the carbon dioxide gas. is stored in the gas absorption container 9C.

2) By rotating the hexagonal cock 5 to connect the measuring tube 6a and the force absorption container 8C and pulling up the piston 6C, the liquid level of the absorption liquid 8e is raised to the position of the platinum wire 8a of the thin tube.

3) Rotate the hexagonal cock 5 to connect the metering pipe 6a and the discharge pipe 10.
By connecting the piston 6C and lowering the piston 6C, the gas in the metering tube 6a is discharged.

4) Perform the same operations as 1) and 2) above for gas absorption containers 9C and 9C.

The above operations complete measurement preparation.

5) Next, rotate the hexagonal hook 5 to connect the sample gas introduction pipe 1 and the gas discharge pipe 10, and use the force 1 to drive the suction pump 4 to flow the sample gas.

6) Rotate the hexagonal cock 5 to connect the sample gas introduction tube 1 and the metering tube 6a, raise the piston 6C, suck up a predetermined amount of the sample gas into the metering tube 6a, and measure it. tube 6
Set the gas pressure in a and record the gas amount and pressure.

7) By rotating the hexagonal hook 5 to connect the measuring tube 6a and the gas absorption container 8c, pressing down the piston 6c to transfer the above sample gas to the gas absorption container 8c, and driving the rotator 8g. , carbon dioxide gas and oxygen gas in the sample gas are absorbed into the absorption liquid 8e.

8) After sufficient absorption, pull up the piston 6C,
The liquid level of the absorption liquid 8e is raised to the position of the platinum wire 8a of the thin tube, and the gas capacity and pressure in the measuring tube 6a are measured and recorded.

9) Calculate the gas absorption amount corresponding to the amount of carbon dioxide gas and oxygen gas from the records in 6) and 8) above.

10) Thereafter, the hexagonal cock 5 is rotated to connect the metering tube 6a and the discharge tube 10, and the piston 6C is depressed to discharge the gas in the metering tube 6a.

11) Regarding the gas absorption container 9C, follow steps 5) to 1 above.
0) to calculate the amount of carbon dioxide gas.

12) Calculate the amount of carbon dioxide gas from the gas amount calculated in 9) and 11) above.

13) After completing the first analysis, rotate the hexagonal knob 5, reset to 4) above, and proceed to the next analysis operation.

14) In addition, in the above operation, the gas absorption container 8C is
) During the absorption operation of 5) above, in the gas absorption vessel 9C,
By performing the operations corresponding to steps 7) to 7) and performing the operations 8) to 10) described above for the gas absorption container 8C during the absorption operation of the gas absorption container 9C, parallel operations are made possible.

(Effects of the Invention) By adopting the above configuration, the present invention measures a sample gas under the same conditions and sequentially introduces the sample gas into a plurality of force absorption vessels, thereby allowing a plurality of gas components to be mixed in parallel. , and made it possible to automatically analyze gas.

[Brief explanation of the drawing]

FIG. 1 is a flow diagram of an automatic gas analyzer that is one embodiment of the present invention. 1: Sample gas introduction tube, 2: Filter, 3: Tiger tube, 4: Suction pump, 5: Hexagonal cock, 5a: Drive motor, 6: Suction discharge section, 6a: Measuring tube, 6b = Pressure gauge, 6
C: Piston, 7: Detection part, 7a゛steer, ping motor, 7b: Feed rod, 7C: Outer frame, 7d Branch, 7e: Middle frame, 7f: Bearing, 7g/timing belt, 8, 9° absorption part, 8a, 8b, 9a, 9b: platinum wire, 8c, 9
c: absorption container, 8d, 9d: auxiliary chamber, 8e, 9e: absorption liquid, 10: discharge pipe, 11: control device, 12: printer.

Claims (1)

[Claims] This is an automatic gas analyzer that connects a sample gas inlet pipe, a gas discharge pipe, a measuring pipe whose piston is driven by a stepping motor, and an absorption device containing different absorption liquids corresponding to the sample gas components to a multi-way cock. A pressure gauge is attached to the measuring tube, a sub-chamber with an open upper part is communicated with the absorption container of the gas absorption device, and the upper part of the absorption container and the multi-way cock are connected by a thin tube containing a liquid level gauge. An automatic gas analyzer characterized by being connected to enable parallel analysis of multiple gas components.