JP3004459U - Infrared gas analyzer - Google Patents

Abstract

(57) [Summary] [Purpose] To provide an infrared gas analyzer in which simple automatic calibration is surely performed by preventing a state in which simple calibration is not continuously performed for a long time. . [Configuration] In an infrared gas analyzer configured to detect a specific measurement target component in the sample gas SG and perform simple calibration at regular time intervals in the measurement mode, the infrared gas analyzer is set to the measurement mode. In some cases, when it is time to perform simple calibration, it is possible to determine whether the concentration of the component to be measured is above a predetermined value and to delay the time to enter the calibration mode until the end of exhaust gas measurement, or the display unit With the function to display the remaining time until the simple calibration mode of
A function was provided to warn that it was time to enter the calibration mode when exhaust gas was being measured when the remaining time became zero.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an improvement of an infrared gas analyzer such as an exhaust gas analyzer used for measuring vehicle exhaust gas during use during vehicle inspection.

[0002]

[Prior art]

 The exhaust gas analyzer measures the components to be measured in the exhaust gas based on the following measurement principle. That is, when infrared rays pass through the exhaust gas, infrared rays in the wavelength range peculiar to the measurement target component contained in the exhaust gas are absorbed, and the concentration of the measurement target component can be measured by measuring the amount of absorption. it can.

At this time, the basis for dealing with the absorption of light is the Lambert-Beer's law, which is expressed by equation (1). ^{_{I t = I 0 · e -kCl}} ...... (1) I 0: intensity of incident light I _t: the intensity of the emitted light k: extinction coefficient l: thickness of the light absorbing layer C: sample concentration

Therefore, the output obtained from the exhaust gas analyzer when the concentration of the sample is C is obtained by the equation (2). _{I t = I 0 · (1} -e -kCl) ...... (2)

FIG. 3 is a block diagram schematically showing the configuration of an exhaust gas analyzer equipped with an analysis unit based on the above measurement principle. In this figure, 1 is an analysis unit and 2 is various input keys. The operation unit 3 displays an analysis result, and a display / external output unit that displays the current state of the device, etc. as necessary. 4 controls each unit of the device based on a key input from the operation unit 2 and performs analysis. A control / arithmetic unit that performs concentration calculation based on a signal from the unit 1 and stores the obtained data, and is, for example, a microcomputer.

FIG. 4 schematically shows a gas flow configuration in the exhaust gas analyzer. In this figure, 5 is a housing, for example, a sample gas inlet 6 (see FIG. 6) is formed on the front surface thereof. Has been done. The sample gas introduction port 6 is connected to the analysis unit 1 provided in the housing 5 via a sample gas flow passage 10 including a dust filter 7, a pressure switch 8, a sampling suction pump 9, and the like. At the same time, a sampling tube 11 having a sampling probe 11 at the tip, a prefilter 12 in the middle, and a drain separator 13 at the other end is connected to the outside thereof. Reference numeral 15 is a span gas inlet connected to the sample gas flow channel 10, and 16 is a drain flow channel provided with a strainer 17, a suction pump 18, etc., provided between the drain separator 13 and the exhaust port 19.

FIG. 5 schematically shows the configuration of the analysis unit 1. The analysis unit 1 is configured, for example, for single cell multiple component measurement. That is, in this figure, 20 is a cylindrical measuring cell, both ends of which are closed by cell windows 20a 1 and 20b 2 made of an infrared permeable material, and which are connected to the sample gas channel 10 and a sample inlet 20c and an exhaust port. A sample outlet 20d connected to 19 is provided. Reference numeral 21 is an infrared light source provided on one cell window 20a side of the measurement cell 20 for irradiating the measurement cell 20.

Reference numeral 22 denotes a detection unit provided on the other cell window 20b side of the measurement cell 20, which is provided, for example, on a concentric circle for CO ₂ measurement, HC measurement, CO measurement, and comparison (FIG. Then, for convenience, it is composed of four infrared detectors (hereinafter, simply referred to as detectors) 23, 24, 25, 26 and optical choppers 27 arranged in a line. 23F, 24F, 25F, and 26F are optical filters provided on the light receiving sides of the detectors 23 to 26, respectively, and are bandpass filters that pass infrared rays in the characteristic absorption band of only the measurement target component. For example, the optical filter 23F of the CO ₂ measuring detector 23 is a bandpass filter that passes infrared rays in the characteristic absorption band of CO ₂ , and the other optical filters 24F and 25F are also the same. On the other hand, the optical filter 26F of the comparison detector 26 is a bandpass filter that allows infrared rays having a wavelength without an absorption band to pass through the coexisting gas in the sample gas.

The optical chopper 27 is rotationally driven by a motor (not shown), and is configured to chop the infrared light that passes through the measuring cell 20 and is incident on the detectors 23 to 26.

The outputs of the detectors 23 to 26 are respectively input to the microcomputer 4 via a preamplifier. For example, the CO ₂ concentration is calculated from the output of the comparison detector 26 to the output of the CO ₂ measurement detector 23. Is obtained by subtracting.

FIG. 6 is a diagram schematically showing the configuration of the front surface portion of the housing 5 of the exhaust gas analyzer. In this figure, 5a is a front panel, and 28 is a mode switching key. In this figure, a mark indicating the state of the device is displayed below the display / external output unit 3, but it goes without saying that these marks are not always or simultaneously displayed. .

In order to measure the concentrations of CO ₂ , HC, and CO contained in the exhaust gas of an automobile using the exhaust gas analyzer having the above-mentioned configuration, the sampling probe 11 of the automobile is set in the measurement mode state of the exhaust gas analyzer. Insert into an exhaust pipe (not shown) to sample the exhaust gas. Here, the measurement mode refers to a state in which the sampling pumps 9 and 18, the infrared light source 21, and the motor of the optical chopper 27 are in the ON state, and the sampling can be immediately performed to perform the measurement.

The sampled exhaust gas (hereinafter, referred to as sample gas SG) is introduced into the measurement cell 20 through the sample gas passage 10. The infrared light emitted from the infrared light source 21 and passing through the measuring cell 20 is the infrared light having a wavelength unique to CO ₂ , HC, and CO contained in the sample gas SG introduced into the measuring cell 20. The amount of infrared light that is absorbed and enters the measuring detectors 23 to 25 is reduced. On the other hand, the amount of infrared light incident on the comparison detector 26 does not decrease because it has a wavelength without an absorption band in the sample gas.

Therefore, the concentrations of CO ₂ , HC, and CO can be obtained by subtracting the outputs of the measurement detectors 23 to 25 from the output of the comparison detector 26, respectively, and the detected CO ₂ , HC, and CO concentrations are displayed on the display / external output unit 3 using liquid crystal provided on the front panel 5a.

As described above, the exhaust gas analyzer is very easy to handle and has the advantage of being able to simultaneously measure the concentrations of a plurality of components to be measured. It is used in vehicle inspection areas.

By the way, generally, in an infrared gas analyzer, the measurement accuracy is lowered with use, and the measurement accuracy is lowered due to drift, etc. Therefore, the sensitivity check is performed by a simple method without using span gas. The simple calibration of the procedure is performed automatically. This simple calibration is described in detail, for example, in Japanese Examined Patent Publication No. 5-2182, and the details thereof will be omitted here. Then, in the conventional exhaust gas analyzer, when the standby mode is switched to the measurement mode, simple calibration is performed.

[0017]

[Problems to be solved by the device]

 However, in the above-mentioned exhaust gas analyzer, etc., the measurement may be performed randomly, and the actual vehicle measurement where gas sampling and component analysis are performed may be continuously performed for a long period of time. As the actual vehicle measurement is continuously performed, the drift amount increases and the measurement accuracy deteriorates accordingly.

The present invention has been made in consideration of the above-mentioned matter, and a simple automatic calibration is surely performed by preventing a state in which the simple calibration is not continuously performed for a long time. The purpose of the present invention is to provide an infrared gas analyzer.

[0019]

[Means for Solving the Problems] In order to achieve the above object, the present invention is configured to detect a specific component to be measured in a sample gas and to perform simple calibration at regular time intervals in a measurement mode. In the infrared gas analyzer that was made, when in the measurement mode or when the time for simple calibration was reached, it was determined whether the concentration of the component to be measured was above a specified value, and the time to enter the calibration mode was measured by measuring the exhaust gas. The feature is that it has a function to delay until the end.

Further, the present invention provides an infrared gas analyzer configured to detect a specific component to be measured in a sample gas and perform simple calibration at a constant time interval in a measurement mode, in a display unit. It has a function to display the remaining time until the next simple calibration mode and a function to warn when the remaining time becomes zero and when it is during exhaust gas measurement it is time to enter the calibration mode. Is characterized by.

[0021]

[Action]

For example, the motor vehicle in the exhaust gas during idling, typically, from where the CO ₂ is contained 5% vol or more, which based on the, the actual vehicle measurement when the CO ₂ concentration is Re der less than 5% vol row If the concentration is 5% or more, it is determined that the actual vehicle is being measured, and the time to enter the calibration mode is delayed until the exhaust gas measurement is completed. Let By doing so, simple automatic calibration can be reliably performed without hindering the actual vehicle measurement.

In addition, the remaining time until the next simple calibration mode is displayed on the display unit, and the predetermined simple automatic calibration mode is displayed by displaying on the display unit or issuing a message that the calibration mode should be entered. The operator can be made aware of the entry.

[0023]

【Example】

 The exhaust gas analyzer as an example of the infrared gas analyzer of the present invention has the same mechanical and structural configurations as those shown in FIGS. 3 to 6, and is shown in FIG. 1 for mode switching. It is different from the conventional exhaust gas analyzer of this kind in that it is configured to be controlled as shown in the flowchart. Hereinafter, description will be given with reference to FIGS. 1 and 2.

Focusing on the fact that the exhaust gas of an idling vehicle usually contains 5% or more of CO ₂ , whether or not a predetermined sampling is performed during the measurement mode, is the measurement performed? To determine. That is, when the CO ₂ concentration is 5% vol or more, it is determined that the predetermined gas sampling is performed and the exhaust gas analysis is performed, and when the CO ₂ concentration is less than 5% vol, the predetermined gas is determined. It is judged that it is in the standby mode, that is, the state where the sampling is not performed and the exhaust gas analysis is not performed.

Now, it is assumed that the exhaust gas analyzer is in the standby mode (step S1). In this standby mode, the sampling pumps 9 and 18, the infrared light source 21, the motor of the optical chopper 27, and the like are off even if the main switch of the power supply is on (see FIG. 2A).

In step S2, it is determined whether or not there is a key input for shifting to the measurement mode. If there is no key input, the process proceeds to NO and returns to step S2. Then, if there is a key input, the process proceeds in the direction of YES to enter the simple automatic calibration mode (step S3).

Then, the measurement mode is set [step S4, see FIG. 2B], and the time t of the counter is set here (step S5). This time t is set to, for example, 30 minutes, for example, even if it is too short or too long, it will interfere with actual vehicle measurement.

It is determined whether or not there is a key input for shifting to the standby mode (step S6), and if there is a key input, the process proceeds in the direction of YES and returns to step S1. Then, if there is no key input, the process proceeds to NO, and it is determined whether or not a predetermined time has elapsed from the set time t (step S7). Here, if the predetermined time has not elapsed from the time t, the process proceeds to NO and returns to step S6. Then, if the fixed time has elapsed, the process proceeds to YES and the countdown is started (step S8).

When the countdown is performed, as indicated by reference numeral 29 in FIG. 6, the remaining time until the next simple calibration mode is, for example, 29:59 (remaining time 29 minutes 59 seconds) below the display unit 3, for example. Is displayed (step S9).

Then, it is judged whether or not the count value has become zero, that is, whether or not it has become the time to enter the simple automatic calibration mode (step S10). If not, the process proceeds to NO, and step Return to S6. On the other hand, if it is zero, the process proceeds to YES, and in step S11, it is determined whether the concentration of the measurement target component, for example, CO ₂ is 5% or more or less (step S11). That is, in this example, the actual vehicle measurement determination level in FIG. 2C is 5% CO ₂ concentration.

If the CO ₂ concentration is less than 5%, the process proceeds to NO in step S11 to enter the simple automatic calibration mode [step S12, see FIGS. 2 (C) and 2 (D)]. That is, in this case, it is determined that the predetermined actual vehicle measurement is not performed even in the measurement mode, and the predetermined simple calibration is performed. When this is completed, the process returns to step S5.

On the other hand, when the CO ₂ concentration is 5% or more, the process proceeds to YES in step S11, and the time to enter the calibration mode is the time α until the end of exhaust gas measurement, as shown in FIG. 2D. Be delayed.

Further, as shown by reference numeral 30 in FIG. 6, the fact that the time for entering the calibration mode has come is displayed as a message, or a voice or a buzzer sound is emitted (step S 13).

Then, it is judged whether or not there is a key input for shifting to the standby mode (step S 14), and if there is no key input, the process proceeds to NO and returns to step S 11. If there is a key input, the process proceeds to YES and returns to step S1.

The present invention is not limited to the above-described embodiment, and the concentration setting value and the time t can be arbitrarily set. Then, the component to be measured may be HC or CO.

Further, the analysis unit 1 does not necessarily have to be configured to measure a plurality of components, and may be configured to be able to measure only a single component to be measured.

The present invention is not limited to the above exhaust gas analyzer, but can be widely applied to infrared gas analyzers in general.

[0038]

[Effect of device]

 As described above, in the present invention, when the infrared gas analyzer is in the measurement mode, when the time for performing the simple calibration comes, it is determined whether the concentration of the component to be measured is the predetermined value or more, and the calibration mode is set. Since the time to enter is delayed until the end of exhaust gas measurement, simple automatic calibration can be reliably performed without hindering actual vehicle measurement.

Further, in the present invention, the remaining time until the next simple calibration mode is displayed on the display unit of the infrared gas analyzer, and the display unit indicates that the calibration mode should be entered or a message is displayed. Since it is configured to emit the light, the operator can be made aware that the predetermined simple automatic calibration mode is entered.

Therefore, according to the present invention, the simple automatic calibration is surely performed and the high analysis accuracy is always maintained by preventing the state where the simple calibration is not continuously performed for a long time. You can

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a flow chart for performing a simple automatic calibration in the infrared gas analyzer of the present invention.

FIG. 2 is a diagram for explaining the operation of the infrared gas analyzer.

FIG. 3 is a diagram schematically showing a configuration of the infrared gas analyzer.

FIG. 4 is a diagram showing a gas flow of the infrared gas analyzer.

FIG. 5 is a diagram schematically showing an example of a configuration of an analysis unit of the infrared gas analyzer.

FIG. 6 is a diagram schematically showing an example of a configuration of a front surface portion of the infrared gas analyzer.

[Explanation of symbols]

 SG ... Sample gas.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Kennosuke Kojima, 2 Higashimachi, Kichijoin Miya, Minami-ku, Kyoto-shi, Kyoto Prefecture Horiba Manufacturing Co., Ltd. (72) Goro Iwami, Higashi-machi, Kichijoin-miya, Minami-ku, Kyoto, Kyoto Prefecture 2 Horiba Seisakusho Co., Ltd. (72) Inventor Kazuhiko Kato 2-31-19, Shiba, Minato-ku, Tokyo Banzai Co., Ltd.

Claims (2)

[Scope of utility model registration request] 1. An infrared gas analyzer configured to detect a specific measurement target component in a sample gas and perform simple calibration at regular time intervals in the measurement mode. An infrared gas analyzer having a function of determining whether or not the concentration of a measurement target component is equal to or more than a predetermined value at the time of calibration and delaying the time to enter the calibration mode until the end of exhaust gas measurement. . 2. An infrared gas analyzer configured to detect a specific component to be measured in a sample gas and to perform simple calibration at regular time intervals in the measurement mode, the next simple calibration on the display unit. Infrared gas characterized by having a function to display the remaining time to the mode and a function to warn that the time to enter the calibration mode has come when the exhaust gas is being measured when the remaining time becomes zero Analyzer.