JP5073844B2 - Absorption spectrometer - Google Patents

Description

  The present invention relates to an absorptiometer that analyzes the concentration of a measurement component contained in a sample gas from the absorbance.

  As an absorption spectrometer of this type, for example, as shown in FIG. 4 of Patent Document 1, ultraviolet light from one ultraviolet light source is divided, introduced into a reference cell and a sample cell, and transmitted through the cells. There is one that detects a reference signal and a sample signal with a single photodetector.

  However, the reference cell is filled with zero gas and can compensate for the zero point fluctuation (drift) of the light source by comparing the sample signal and the reference signal, but it cannot correct the interference due to other components. There is.

  In addition, there is a problem that it is not possible to compensate for a decrease in the amount of light due to dirt or fogging of the transmission window provided in the sample cell.

  On the other hand, as shown in FIG. 1 of Patent Document 1, ultraviolet light from one ultraviolet light source is introduced into a sample cell, and transmitted light transmitted through the cell is measured with a measurement filter that transmits ultraviolet light having an absorption wavelength as a measurement component. There is one in which a sample signal and a reference signal are detected by two photodetectors through a band-pass filter that transmits light having a wavelength that does not overlap the absorption wavelength band of ultraviolet light.

  However, this can correct interference due to other components by the difference between the sample signal and the reference signal. However, since multiple photodetectors are used, the sensitivity varies depending on changes in the ambient temperature. Occurs, and it is difficult to compensate (decrease in relative sensitivity).

  Furthermore, there is a problem that the wavelength characteristics of the ultraviolet light source change due to a change in ambient temperature, and the balance between the photo detector on the sample side and the reference photo detector changes.

Patent No. 3078983

  Accordingly, the present invention has been made to solve the above-mentioned problems all at once, and compensates for drift of the light source, correction of other component interference, correction of a decrease in the amount of light due to contamination of the transmission window of the sample cell, The main objective of the present invention is to provide an absorption spectrometer capable of reducing sensitivity drift.

That is, the absorption spectrometer according to the present invention includes two light sources having different emission spectrum wavelength bands, a reference cell filled with zero gas , a sample cell supplied with sample exhaust gas , and light from the light source. A light guide mechanism for introducing the cell and the sample cell from one end side, a light detection unit provided on the other end side of the reference cell and the sample cell, for detecting light transmitted through the cells, and the two light sources, respectively together to alternately light up the two light sources by off and provided with a control unit for controlling to detect the transmitted light when the light detection unit, each of the two light sources is lit, the light Two photodetectors provided corresponding to the reference cell and the sample cell, respectively, or the reference Characterized in that Le and the sample cell is a single photodetector provided to correspond.

  In such a case, since the reference cell and the sample cell are used, the light source drift can be compensated. Further, by comparing the detection results obtained when the two light sources are turned on, it is possible to cancel other component interference and reduce the sensitivity drift of the light detection unit. Furthermore, by using a light source that emits light that is different from the absorption wavelength band of the sample, it is possible to correct a decrease in the amount of light due to contamination of the transmission window of the sample cell. Further, since the two light sources are alternately turned on, the above corrections can be performed in substantially real time.

  It is desirable that one of the two light sources emits near-infrared light from visible light, and the other emits ultraviolet light, as preferably used for ultraviolet absorption analysis.

  According to the present invention configured as described above, it is possible to provide an absorptiometer capable of realizing light source drift compensation, correction of other component interference, correction of light amount reduction due to contamination of a transmission window of a sample cell, and reduction of sensitivity drift. Can do.

The typical block diagram of the absorption spectrometer which concerns on one Embodiment of this invention. The figure which shows the detection method in the same embodiment.

  An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram of the absorption spectrometer 1 according to the present embodiment, and FIG. 2 is a diagram illustrating a control method of the light sources 2 and 3 and the light detection unit 7 of the absorption spectrometer 1.

<Device configuration>
Absorption analyzer 1 according to this embodiment is for measuring the concentration of exhaust gas (sample gas) NO 2 _(measured component) contained in using an ultraviolet absorption method, as shown in FIG. 1, NO ₂ Are supplied with an ultraviolet light source 2 that irradiates ultraviolet light in the light absorption wavelength band, a visible light source 3 that emits visible light in a wavelength band different from the absorption wavelength band of NO ₂ , a reference cell 4 serving as a reference, and a sample gas. The sample cell 5, the light guide mechanism 6 that splits the light from the light sources 2 and 3 and introduces the light into the reference cell 4 and the sample cell 5 from one end, and the reference cell 4 and the sample cell 5. A light detection unit 7 provided on the other end side for detecting light transmitted through the cells 4 and 5, a control unit 8 for controlling the light sources 2 and 3 and the light detection unit 7, and a detection signal from the light detection unit 7 Receive the given performance And an arithmetic unit 9 that performs an arithmetic operation.

  Below, each part 2-9 is demonstrated.

The ultraviolet light source 2 is a light emitting diode that emits ultraviolet light having a center wavelength of 360 nm to 400 nm. The visible light source 3 is a light emitting diode that emits visible light in a wavelength band with little NO ₂ absorption. These light sources 2 and 3 are disposed at substantially the same position.

The reference cell 4 has a hollow column shape, and both ends thereof are sealed by a transmission window 41 formed of a material (for example, quartz) having good visible light transmittance and ultraviolet light transmittance. The reference cell 4 is filled with nitrogen gas (N ₂ gas) having no absorption wavelength band for ultraviolet light as a reference gas.

  The sample cell 5 has a hollow columnar shape provided in parallel with the reference cell 4, and both end portions thereof are made of a material having good visible light transmittance and ultraviolet light transmittance (for example, quartz). The window 51 is sealed. Further, a sample introduction port 52 for supplying a sample gas and a sample discharge port 53 for discharging the sample gas are provided on the side peripheral surface.

  The light guiding mechanism 6 includes a half mirror 61 as a light splitting element that spatially divides the visible light from the visible light source 3 and the ultraviolet light from the ultraviolet light source 2 into one that transmits and one that reflects. And a reflection mirror 62 for guiding the light reflected by the half mirror 61 to the reference cell 4. Further, the light transmitted through the half mirror 61 is introduced into the sample cell 5.

  The light detection unit 7 includes a reference light detector 71 provided on the other end side of the reference cell 4 and a sample light detector 72 provided on the other end side of the sample cell 5. These photodetectors 71 and 72 can be composed of, for example, a silicon photodiode or a photomultiplier tube. The reference photodetector 71 outputs a reference signal, and the sample photodetector 72 outputs a sample signal.

  The control unit 8 controls the visible light source 3, the ultraviolet light source 2, the reference light detector 71, and the sample light detector 72, and the device configuration includes a computer and an electric circuit such as an analog or digital circuit. Yes.

  Then, the control unit 8 alternately turns on the visible light source 3 and the ultraviolet light source 2 and transmits the reference light detector 71 and the sample light detector 72 when the visible light source 3 and the ultraviolet light source 2 are turned on. It is controlled to detect light.

  More specifically, as shown in FIG. 2, the control unit 8 controls the visible light source 3 and the ultraviolet light source 2 to be switched on at regular intervals in a cycle of 30 Hz to 100 Hz. In this way, since the alternate lighting is performed so that it can be regarded as almost simultaneous, the following baseline correction and interference correction can be performed almost simultaneously.

  In addition, the control unit 8 converts the visible transmitted light that has passed through the reference cell 4 and the visible transmitted light that has passed through the sample cell 5 at the timing when the visible light source 3 is turned on, into a reference photodetector 71 and a sample photodetector 72. Control to detect.

  Further, at the timing when the ultraviolet light source 2 is turned on, the ultraviolet light transmitted through the reference cell 4 and the ultraviolet light transmitted through the sample cell 5 are detected by the reference light detector 71 and the sample light detector 72. Control.

Then, the control unit 8, by controlling this manner, the operation unit 9, as shown in FIG. 2, it is possible to obtain four signals S ₁ to S _4.

The S ₁ signal is “UV transmitted light sample signal S _UV ”, the S ₂ signal is “visible transmitted light sample signal S _VIS ”, and the S ₃ signal is “UV transmitted light reference signal R _UV”. The S4 signal is a “visible transmitted light reference signal R _VIS ”.

The calculation unit 9 acquires the detection signals S _{1 to} S ₄ from the reference light detector 71 and the sample light detector 72 and performs a predetermined calculation to calculate the absorbance and concentration of NO _2. As in the control unit 8, the configuration includes a computer and an electric circuit such as an analog or digital circuit.

Specifically, the calculation unit 9 calculates a ratio between the “sample signal S _{UV of} ultraviolet transmission light” and the “reference signal R _UV of ultraviolet transmission light” to compensate for a measurement error due to drift of the ultraviolet light source 2. To do.

Further, the calculation unit 9 calculates the ratio between the “visible transmitted light sample signal S _VIS ” and the “visible transmitted light reference signal R _VIS ” to compensate for a drift of the visible light source and the like. Further, the contamination of the transmission window 51 of the sample cell 5 can be detected, and the light amount reduction of the ultraviolet light due to the contamination of the transmission window 51 is corrected and calculated.

Further, the calculation unit 9 calculates the difference between the “ _UV transmitted light sample signal S _UV ” and the “visible transmitted light sample signal S _VIS ”, thereby using a component other than the measurement component contained in the sample gas. Interference is calculated, and other component interference is corrected.

  As described above, the calculation unit 9 compensates for the light source drift, corrects the interference of other components other than the measurement component, and corrects the light amount decrease due to the contamination of the transmission window 51 of the sample cell 5 to obtain the concentration of the measurement component in the sample gas. calculate.

<Effect of this embodiment>
According to the absorption spectrometer 1 according to the present embodiment configured as described above, it has two optical paths and two wavelengths, and “sample signal S _{UV for} ultraviolet transmitted light”, “sample signal S _{VIS for} visible transmitted light”, “ Since the concentration of the measurement component is calculated using the reference signal R _{UV of the} ultraviolet transmitted light and the reference signal R _VIS of the visible transmitted light, compensation for drift of the light sources 2 and 3, other than the measurement component The concentration of NO ₂ can be calculated by correcting other component interference, correcting the decrease in light amount due to dirt or clouding of the transmission window 51 of the sample cell 5, and compensating for the sensitivity drift, thereby improving the measurement accuracy.

  Further, since elements such as drifts of the light sources 2 and 3, interference of other components other than the measurement component, dirt on the transmission window 51 of the sample cell 5, and sensitivity drift can be individually detected, the maintainability can be improved. it can.

  Furthermore, since the absorption spectrometer 1 of the present embodiment does not use an optical filter, the light loss can be reduced as much as possible, and the S / N ratio can be increased.

<Other modified embodiments>
The present invention is not limited to the above embodiment. In the following description, the same reference numerals are given to members corresponding to the above-described embodiment.

  For example, a mechanical chopper can be provided between the visible light source 3 and the ultraviolet light source 2 and the half mirror 61, and the sample photodetector and the reference photodetector can be a single photodetector. In this case, it is necessary to perform AC signal processing.

  Moreover, in the said embodiment, although the visible light source 3 was used, you may use the light source which irradiates the light of a visible light wavelength range to a near-infrared-light wavelength range.

  In addition, some or all of the above-described embodiments and modified embodiments may be combined as appropriate, and the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention. .

DESCRIPTION OF SYMBOLS 1 ... Absorption spectrometer 2 ... Ultraviolet light source 3 ... Visible light source 4 ... Reference cell 5 ... Sample cell 6 ... Light guide mechanism 7 ... Light detection part 8 ... Control Part

Claims (2)

Two light sources with different emission spectrum wavelength bands;
A reference cell filled with zero gas ,
A sample cell to which sample exhaust gas is supplied;
A light guide mechanism for introducing light from the light source into the reference cell and the sample cell from one end side;
A light detection unit that is provided on the other end side of the reference cell and the sample cell and detects light transmitted through the cells;
A control unit that turns on and off each of the two light sources to alternately turn on the two light sources and controls the light detection unit to detect transmitted light when each of the two light sources is turned on. and,
The photodetector is two photodetectors provided corresponding to the reference cell and the sample cell, respectively, or a single photodetector provided corresponding to the reference cell and the sample cell. Absorption spectrometer.   The absorptiometer according to claim 1, wherein one of the two light sources emits near-infrared light from visible light, and the other emits ultraviolet light.