JP3172571B2 - Gas concentration measuring method and device using reference gas concentration adjusting method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for measuring a gas concentration by a reference gas concentration adjusting method using a non-dispersive infrared gas analyzer of a fluid modulation / comparison measurement type.

[0002]

_2. Description of the Related Art As a method for measuring the CO ₂ concentration in the atmosphere, a method using a non-dispersive infrared gas analyzer of a comparative measurement type by a fluid modulation method is known. This is to introduce the reference gas and the sample gas alternately into the cell provided in the optical system by the comparison gas line and the sample gas line, respectively.
The infrared light transmitted from the light source to the cell is detected, and the concentration of the sample gas is analyzed based on the detected difference.

[0003]

However, even in the above-mentioned fluid modulation method, when the concentration fluctuates in a relatively wide range such as CO _{2 in} the atmosphere, the measurable range (full scale) is expanded. Technical issues that must be performed,
For example, there is a disadvantage that the influence on the measured value due to a change in the gas density in the cell caused by a change in the atmospheric pressure or the like cannot be ignored.

[0004] The present invention has been made in view of such circumstances,
It is an object of the present invention to provide a gas concentration measuring method using a reference gas concentration adjusting method which does not require a concept of a measurement range in a gas analyzer, has no span drift, and has a stable sensitivity, and an apparatus therefor.

[0005]

According to the present invention, means for solving the above-mentioned problems are constituted as follows. That is, in the first invention, the reference gas and the sample gas are alternately supplied to the cell at a constant period and a constant amount, and the cell is irradiated with infrared rays from the light source, and the transmitted light is received by the detector. A gas concentration measurement method using a fluid modulation / comparison measurement type gas analyzer which performs a concentration analysis of a sample gas by performing a reference gas so that a detection output from the gas analyzer becomes zero. Is adjusted, and the concentration of the reference gas is used as the concentration of the sample gas.

In the second invention, a reference gas and a sample gas are alternately supplied to a cell at a constant period and a constant amount, and the cell is irradiated with infrared rays from a light source, and the transmitted light is detected by a detector. In a gas concentration measurement device provided with a gas analyzer of a fluid modulation / comparison measurement system which performs concentration analysis of a sample gas by receiving light, a detection signal from the gas analyzer is received, and a detection value thereof is received. Reference gas adjusting means for variably adjusting the concentration of the reference gas to be zero is provided in the reference gas supply line, and the concentration of the reference gas adjusted by the reference gas adjusting means is used as the concentration of the sample gas. I have.

[0007]

The gas analyzer of the comparative measurement type based on the fluid modulation method has a characteristic that when the concentration of the sample gas is equal to the concentration of the reference gas (comparison gas), the detected value from the gas analyzer becomes zero. Therefore, by the reference gas adjusting means,
If the concentration of the reference gas is adjusted so that the detected value from the gas analyzer becomes zero, the concentration of the reference gas at that time becomes equal to the concentration of the sample gas, and the value can be used as the concentration of the sample gas. .

In this case, the concept of the so-called full scale itself does not exist, and the measurement range is determined by the capability of the reference gas adjusting means regardless of the measurable range of the gas analyzer. There will be no technical issues.

Further, in order to make the detection value from the gas analyzer zero by the reference gas adjusting means,
There is no span drift of the gas analyzer itself, and the measured value is not affected.

[0010] Further, since the concentrations of both gases in the cell are matched, even if there is a change in atmospheric pressure or concentration, there is no influence on the measured value due to the change in gas density.

[0011]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 shows a measuring apparatus for carrying out a gas concentration measuring method according to the reference gas concentration adjusting method of the present invention. Reference numeral 1 denotes a sample gas line for supplying a gas to be measured, and 2 denotes a reference gas. The comparison gas line 2 receives the supply of the reference gas from the zero gas purifier 3 and the reference gas adjusting means 5 connected to the standard gas cylinder 4, and both the gas lines 1 and 2 have a constant period. Each of the cells is connected to a gas inlet of a pair of cells 9 and 10 via flow path switching means 6 including a rotary valve or an electromagnetic valve for switching a gas flow path and two connection pipes 7 and 8. The gas outlets 9 and 10 are connected to an exhaust line 11.

The above-mentioned zero gas purifier 3 purifies and supplies a gas having no infrared absorption, for example, N ₂ gas. The standard gas cylinder 4 is filled with, for example, a predetermined high-concentration CO ₂ gas. As described later, both gases (N ₂ , CO ₂ ) are mixed by the gas adjusting means 5 so that the detection signal value from the detector 16 becomes zero, and the concentration is determined as the CO ₂ concentration in the sample gas by the indicator 21. Is displayed. The zero gas purifier 3 may be an N ₂ cylinder, or may be an apparatus provided with an adsorbent for removing a component to be measured (CO ₂ ) from a sample gas. In that case, zero gas is purified from the sample gas.

A light source 14 is provided at one end of each of the cells 9 and 10 described above.
15 is provided, a gas introduced into each of the cells 9 and 10 is irradiated with infrared rays, and a difference in the amount of transmitted light is periodically superimposed by a condenser microphone type detector 16 provided on the other end side. , And the detection difference amount can be amplified by the amplifier 19 and output as a detection signal. In addition,
Reference numeral 17 denotes a condenser membrane, reference numeral 18 denotes a fixed electrode, and a portion surrounded by a chain line is a gas analyzer of a comparative measurement type using a fluid modulation method.
20 is shown.

The detection signal from the detector 16 is input to the above-mentioned reference gas adjusting means 5, and the reference gas adjusting means 5 outputs the signal from the zero gas purifier 3 so that the detection signal value becomes zero. The flow rates of the zero gas and the standard gas from the standard gas cylinder 4 are feedback-adjusted, and the concentration of the reference gas is adjusted to the CO ₂ in the sample gas at that time.
The density is displayed on the indicator 21.

That is, in the gas analyzer 20 of the comparative measurement type using the fluid modulation method, when the concentration of the sample gas becomes equal to the concentration of the reference gas (comparison gas), the detection signal value from the gas analyzer 20 becomes zero. There is a characteristic, and as described above, by adjusting the concentration of the reference gas to be equal to the concentration of the sample gas using the characteristic, the concentration of the reference gas can be used as the concentration of the sample gas. is there.

The reference gas adjusting means 5 for adjusting the concentration of the reference gas is, for example, a mass flow meter provided in each of two gas flow paths as disclosed in Japanese Patent Publication No. 59-41126, and is separated from both gas flow paths. The two gas flow paths are merged and connected to the comparison gas line 2, and the concentration of the standard gas diluted by the zero gas, that is, the reference gas at that time is provided. A device configured to convert the concentration and output a signal to the indicator 21 is used.

The present invention is not limited to the number of cells in the above-described embodiment, but is a fluid modulation system in which a reference gas and a sample gas are alternately supplied to a single cell at a constant period and a constant amount. Needless to say, the present invention can be applied to a system.

As described above, in the measuring method for matching the concentration of the reference gas with the concentration of the sample gas, there is no concept of a so-called full scale, and the reference gas is independent of the measurable range of the gas analyzer 20. The measurement range is determined by the capability of the adjusting means 5, and there is an advantage that the technical problem of expanding the full scale of the gas analyzer 20 does not exist, which is particularly suitable for the measurement of the CO ₂ concentration having a large fluctuation range.

Further, there is no span drift itself of the gas analyzer 20, and there is no influence on the measured value, so that the indication stability is improved.

Further, since the gas concentrations in the cells 9 and 10 are made to match, even if there is a change in air pressure or a change in temperature, the change in gas density does not affect the measured value, and the reliability of the measured value is improved. I do.

[0021]

As described above, according to the method of the present invention, the concentration of the reference gas is adjusted so that the detection output from the gas analyzer becomes zero, and the concentration of the sample gas is adjusted based on the concentration of the reference gas. Therefore, it is not necessary to enlarge the full scale, which is suitable for measuring the CO ₂ concentration having a large fluctuation range.

Further, since there is no span drift of the gas analyzer, there is no influence on the measured value and the indication stability is improved.

Further, since the gas concentrations in both cells are made to match, even if there is a pressure change or a temperature change, there is no influence on the measured value due to the change in gas density, and the reliability of the measured value is improved.

By employing a highly reliable flow control means such as a mass flow meter as a reference gas adjusting means for variably adjusting the concentration of the reference gas, the apparatus can be constructed without providing a separate complicated circuit. be able to.

[Brief description of the drawings]

FIG. 1 is a circuit diagram of a gas concentration measuring device for performing a gas concentration measuring method according to a reference gas concentration adjusting method of the present invention.

[Explanation of symbols]

2: Reference gas supply line (comparison gas line), 5: Reference gas adjusting means, 9, 10, cell, 16: detector, 20: gas analyzer.

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Masaru Miwa 3-8-8 Sasao Nishi, Toin-cho, Inaba-gun, Mie Prefecture (72) Inventor Osamu Kumazaki 2-301 Shimada, Tenpaku-ku, Nagoya City, Aichi Prefecture (72) Invention Person Shuichi Ishimoto 2 Higashi-cho, Kichijoin-gu, Minami-ku, Kyoto, Kyoto, Japan (72) Inventor Mikasa Former Mikasa Moto 2 Higashi-cho, Kichijoin-gu, Kyoto, Kyoto, Japan Norio 2 Higashi-cho, Kichijo-in Palace, Minami-ku, Kyoto, Kyoto, Japan (72) Inventor Takeshi Yamada 2 Higashi-cho, Kichijo-in Palace, Minami-ku, Kyoto, Kyoto, Japan (56) References to HORIBA, Ltd. 2-272361 (JP, A) JP-A-1-174943 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) G01N 21/00-21/01 G01N 21/17-21 / 61 JICST Airu (JOIS)

Claims (2)

(57) [Claims] 1. A method according to claim 1, wherein a reference gas and a sample gas are alternately supplied to the cell at a fixed period and a fixed amount, and a light source irradiates the cell with infrared rays, and the transmitted light is received by a detector. A gas concentration measurement method using a fluid modulation / comparison measurement type gas analyzer that performs a concentration analysis of a sample gas, wherein a concentration of a reference gas is adjusted so that a detection output from the gas analyzer becomes zero. A gas concentration measuring method using a reference gas concentration adjusting method, wherein the gas concentration is adjusted and the concentration of the reference gas is used as the sample gas concentration. 2. A method according to claim 1, wherein a reference gas and a sample gas are alternately supplied to the cell at a fixed period and a fixed amount, and a light source irradiates the cell with infrared rays, and the transmitted light is received by a detector. In a gas concentration measurement device provided with a gas analyzer of a fluid modulation / comparison measurement method for performing a concentration analysis of a sample gas, a reference is made so that a detection signal from the gas analyzer is received and the detection value becomes zero. A reference gas concentration adjusting method, wherein reference gas adjusting means for variably adjusting the concentration of gas is provided in a reference gas supply line, and the concentration of the reference gas adjusted by the reference gas adjusting means is used as the concentration of the sample gas. Gas concentration measuring device.