JPH04125446A - Spectrophotometer - Google Patents

Abstract

PURPOSE:To obtain a spectrophotometer with good measurement results by performing measurement of absorption amount of transmission light of a replaceable flow cell, cleaning of the flow cell and status determination by the flow cell absorption amount with the cleaning solution supplied. CONSTITUTION:At the time of measurement, cleaning fluid is continuously supplied from a cleaning vessel 12 into a flow cell 4 in a sub-routine, while absorbency of the flow cell 4 is measured. When the flow cell 4 is contaminated, the absorbency gradually decreases accompanying cleaning to approach a constant value, but when it is not contaminated, it suddenly approaches zero. Determination is made as to whether a rate of change in absorbency is in a predetermined range, and when it is not in the range and pre-specified cleaning time has elapsed, a failure in cleaning function is displayed. When the rate of change in absorbency is indicated as normal, it is compared with an initial set value before measurement, and if it is within the predetermined range, a specimen is placed to start measurement. Thus a spectrophotometer with good measurement results can be obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a spectrophotometric needle, in particular a spectrophotometric needle equipped with a flow cell.

[Conventional technology]

There are spectrophotometers equipped with a flow cell for performing absorption analysis of samples and industrial measurements. This spectrophotometer can continuously supply a sample to a flow cell and can continuously perform spectroscopic analysis of the sample.

This type of spectrophotometer generally does not have a judgment function for determining the lifespan of the cell or a correction function for correcting measurement errors due to differences in optical path length between the old and new cells when replacing the cell. First, these judgments are made by the measurer based on the measurement results of the sample supplied to the cell.

[Problem to be solved by the invention]

In the conventional spectrophotometer mentioned above, cell life etc. are determined based on the measurement results of the sample, but the measured value of the sample to be measured is usually not constant, and it is difficult to make accurate judgments and corrections based on it. I can't do it. That is, the conventional spectrophotometer cannot accurately grasp the state of the cell, making it difficult to obtain good measurement results.

The purpose of the present invention is to be able to accurately determine the state of a flow cell,
An object of the present invention is to provide a spectrophotometer that can obtain good measurement results.

[Means to solve the problem]

The spectrophotometer according to the present invention includes a replaceable flow cell,
An absorbance measurement device for measuring the amount of light absorbed by the flow cell, a cleaning device for supplying cleaning liquid to the flow cell for cleaning, and a flow cell state based on the absorbance of the flow cell supplied with the cleaning liquid. and judgment means for making judgments.

[Effect]

In the spectrophotometric needle of the present invention, the determining means determines the state of the flow cell based on the amount of light absorbed by the flow cell to which the cleaning liquid is supplied. Therefore, the determining means can accurately determine the state of the flow cell regardless of sample fluctuations. Therefore, the spectrophotometer according to the present invention provides good measurement results.

〔Example〕

FIG. 2 shows a schematic configuration of an embodiment of the present invention.

In the figure, a spectrophotometer 1 includes a light source device 2 and a detector 3.
and a flow cell 4 disposed between the light source device 2 and the detector 3.

The light source device 2 includes a light source chamber 5 and a spectrometer 6. The light source chamber 5 is equipped with a light source lamp such as a tungsten lamp, and is capable of irradiating light toward the spectrometer 6 . The spectroscope 6 includes, for example, a prism, and is capable of irradiating only light of a specific wavelength out of the light from the light source chamber 5 toward the flow cell 4 .

The detector 3 is a device for detecting the amount of light absorbed from the spectrometer 6 that passes through the flow cell 4, and has a display device 7 for displaying the detection results. This display device 7
is, for example, a CRT or a recording drum.

The flow cell 4 is composed of a tube made of quartz glass, for example. One end of a pipe 8 having a liquid feeding pump 10 is connected to the inlet side of the flow cell 4 . A switching valve 9 is connected to the other end of the pipe 8. A sample container 11 and a cleaning liquid container 12 are connected to the switching valve 9 .

The sample container 11 is filled with a solution of a sample to be analyzed. Further, the cleaning liquid container 12 is filled with a cleaning liquid for cleaning the flow cell 4 . This cleaning liquid is, for example, water, a surfactant, hydrochloric acid, hypochlorous acid, or the like.

The spectrophotometer 1 has a control section 20 as shown in FIG. The control unit 20 includes a CPU 21, a ROM 22, an RA
It is equipped with M23 and I10 ports 24 for external connections. A key input section 25, a detector 3, and other input sections are connected to the I10 boat 24. Similarly, the I10 boat 24 includes the light source device 2 and the liquid pump 10.
, a switching valve 9, a display device 7 and other output parts are connected thereto.

Next, the operation of the spectrophotometer 1 described above is explained in FIGS. 1A and 1B.
The explanation will be made according to the control flowchart shown in the figure and FIG. 1C.

When a main switch (not shown) is turned on, initial settings such as setting the prism in the spectrometer 6 to the initial state are performed in step S1 of FIG. 1A.

Once the initial settings are completed, in step S2, the program determines whether the spectrophotometer 1 is operated for the first time after manufacturing. This judgment is made when the cutting motion recognition flag is rl, (
ON) or rO” (oFF). Note that this flag is set to "1" at the time of manufacture. If the flag is "1", it is determined Yes in step S2, and the program moves to step S3.

In step S3, the liquid feed pump IO is operated to supply the cleaning liquid from the cleaning liquid container 12 through the pipe 8 into the flow cell 4. Next, in step S4, the absorbance A of the flow cell 4 to which the cleaning liquid has been supplied is measured. To measure the absorbance A, the light source device 2 is activated and the spectrometer 6 irradiates the flow cell 4 with only light of a predetermined wavelength out of the light from the light source chamber 5 . Then, the light transmitted through the flow cell 4 is received by the detector 3 and the absorbance A is measured. When the measured absorbance A becomes stable, the absorbance A is stored in a predetermined memory in step S5.

Next, in step S6, the cell correction coefficient K is set to 1. Subsequently, in step S7, the above-mentioned initial motion recognition flag is set to rO, (OFF).

This will allow you to turn the main switch of spectrophotometer 1 on from now on.
If the answer is NO, it is determined as NO in step S2,
The processes from step S3 to step S7 are not executed.

In step S8, it is determined whether the measurement key has been pressed. In step SIO, it is determined whether the correction key has been pressed. In step 312, it is determined whether the end key has been pressed. In step S14, it is determined whether any other key has been pressed. That is, here, the system waits for any input key to be operated.

If the stepping motion measurement key is pressed, the program moves from step S8 to step S9 and executes the measurement subroutine of FIG. 1B.

In the measurement subroutine, in step 316, cleaning liquid is continuously supplied from the cleaning liquid container 12 into the flow cell 4, and cleaning of the flow cell 4 is started. Next, step S
In step 17, the absorbance C of the flow cell 4 during cleaning is measured. If the flow cell 4 is dirty, the absorbance C gradually decreases and approaches a constant value, as shown in FIG. 4A. In step 31B, the rate of change in absorbance C is calculated.

The rate of change is calculated by smoothing the graph in Figure 4A (Figure 4B),
It is obtained by differentiating the amount of change in absorbance C.

The graph of the rate of change corresponding to the graph in Figure 4B is shown in Figure 4C.
It will look like the figure. As can be seen from the graph, the rate of change in absorbance C approaches O as cleaning progresses.

Note that when the flow cell 4 is not contaminated, the rate of change quickly approaches O.

In step S19, it is determined whether the rate of change in absorbance C is within a predetermined range close to 0 (range Y in FIG. 4C).

If the rate of change is not close to O (in the region of X in Figure 4C), the program proceeds from step S19 to step S20.
to move to. In step S20, it is determined whether the cleaning time of the flow cell 4 has elapsed over a preset time. Note that this cleaning time is usually set to a sufficient time to complete cleaning. If the cleaning time has not elapsed, the program returns to step 316 and the cleaning operation of the flow cell 4 is repeated.

If the rate of change in absorbance C is not close to O and the cleaning time has elapsed, the program moves from step S20 to step S21. In this case, it is considered that the normal cleaning operation is not being performed, so in step S21,
It is displayed that there is an abnormality in the cleaning function of the flow cell 4. Then, after stopping the cleaning operation in step S22, the program returns to the main routine of FIG. 1A.

When the cleaning of the flow cell 4 progresses normally and the rate of change in absorbance C reaches a region close to 0 (region Y in Fig. 4C), the cleaning is considered to have been completed, and the program proceeds to step S1.
9, the process moves to step S23, and cleaning of the flow cell 4 is stopped. Then, in step S24, the absorbance C
It is determined whether or not the absorbance is within a certain range based on the absorbance A.

In this range, unwashable dirt and scratches may cause the flow cell to
This corresponds to the range where it is considered that absorbance measurement is no longer suitable. If the absorbance C is within this certain range, it is considered that the flow cell 4 has been sufficiently cleaned and can be used, so the program moves to step S25.

In step 325, a sample is supplied into the flow cell 4. Here, the switching valve 9 is operated to connect the piping 8 and the sample container 11, and the liquid feed pump 10 is operated to supply the sample in the sample container 11 into the flow cell 4. Then, in step S26, the absorbance of the flow cell 4 to which the sample is supplied is measured. Next, in step S27, the measurement results measured in step S26 are corrected.

This correction includes correction of measurement errors due to differences in optical path length based on individual differences in the flow cells 4. For this correction, the stored correction coefficient K is used. Specifically, the measurement result obtained in step S26 is multiplied by a correction coefficient K. In step 32B, the corrected measurement results are displayed on the display device 7. When the processing at step 32B is completed, the program returns to the main routine of FIG. 1A.

In step S24, if the absorbance C is not within a certain range based on the absorbance A, it is considered that the flow cell 4 has reached the end of its useful life, so the program moves to step S29. Then, in step S29, a flow cell replacement display is displayed to prompt the operator to replace the flow cell 4, and in step S330, the flow cell 4 is replaced.
Waiting for replacement. Once the flow cell 4 has been replaced, the program returns to the main routine of FIG. 1A.

When the Sarasho Toyomune Seigin valve operator presses the correction key, the program moves from step SIO to step Sll and executes the correction subroutine shown in FIG. 1C. This correction subroutine normally executes a new correction coefficient K when the flow cell 4 is replaced.
is executed to obtain.

In the correction subroutine, a cleaning liquid is supplied to the flow cell 4 in step S31. Next, in step S32, the absorbance B of the flow cell 4 to which the cleaning liquid has been supplied is measured. Then, in step S33, this absorbance B is stored.

Next, in step 334, a correction coefficient K for the flow cell 4 is calculated. The correction coefficient is obtained by dividing the stored absorbance A by the absorbance B and multiplying the obtained value by the stored correction coefficient K.

Thereby, the correction coefficient K of the new flow cell 4 can be obtained from the correction coefficient K of the old flow cell 4 based on the difference between the absorbance A and the absorbance B. Next, in step 335, the value of absorbance B is substituted for the stored absorbance A.

The new absorbance A value changed here is used as reference data for calculating the correction coefficient K when the program executes the correction subroutine next time. Step S
Upon completion of step 35, the program returns to the main routine of FIG. 1A.

If this correction coefficient is corrected, it will be possible to perform subsequent measurements (1B
The correction coefficient K (step 527) used in FIG.

If the operator presses the end key, the program moves from step 312 to step S13.

In step S13, the flow cell is cleaned.

Upon completion of step 313, the program ends.

Note that if the operator presses any other key without pressing the end key, the program proceeds from step S14 to step S.
15. In step 315, an action corresponding to another key pressed by the operator is performed, such as typing out the data displayed in step 32B.

As described above, in the spectrophotometer 1 of the present embodiment, the cleaning state and life of the flow cell 4 are determined based on the absorbance of the flow cell 4 to which a cleaning liquid that can easily be obtained under certain conditions is supplied, and the flow cell 4 is corrected. The coefficient K is calculated. Therefore, according to this embodiment, the state of the flow cell 4 can be accurately determined and good measurement results can be obtained.

〔Effect of the invention〕

The spectrophotometric needle of the present invention is equipped with the above-described determining means for determining the state of the flow cell using a cleaning liquid. Therefore, according to the present invention, a spectrophotometer that can accurately determine the state of the flow cell and obtain good measurement results can be realized.

[Brief explanation of the drawing]

1A, 1B, and 1C are control flowcharts of an embodiment of the present invention, FIG. 2 is a schematic configuration diagram of the embodiment, FIG. 3 is a schematic block diagram of the control section, and FIG.
Figures A and 4B are graphs showing changes in absorbance C over time;
FIG. 4C is a graph showing the rate of change in absorbance C. DESCRIPTION OF SYMBOLS 1... Spectrophotometer, 2... Light source device, 3... Detector, 4... Flow cell, 12... Cleaning liquid container. Patent applicant Shimadzu Corporation Representative Patent attorney Yukio Ono

Claims (1)

[Claims] (1) a replaceable flow cell; an absorbance measuring device for measuring the amount of light absorbed passing through the flow cell; a cleaning device for supplying a cleaning liquid to the flow cell for cleaning; a determining means for determining the state of the flow cell based on the amount of light absorbed by the flow cell.