JPH0213857A - Spectrum analyser - Google Patents

Abstract

PURPOSE:To measure spectral luminous intensity by a spectrophotometer while a specimen is held to a suction nozzle by providing a spectral luminous intensity measuring cell part to the specimen suction nozzle to suck the liquid specimen arranged to an automatic sampler. CONSTITUTION:A specimen is sucked in a specimen suction nozzle 3 from the specimen container 26 positioned at a specimen suction position 40. When the specimen is sucked in the specimen suction nozzle 3, a support shaft 13 is moved upwardly to raise the specimen suction nozzle 3. Subsequently, the support shaft 13 is revolved to move the specimen suction nozzle 3 to the part above the insert hole 33 of a spectrophotometer 4. Then, the support shaft 13 is moved downwardly to insert the specimen suction nozzle 3 in the insert hole 33 to measure the absorbancy of the specimen sucked and held in the cell part 6. The measured data is sent to a computer from an absorbancy measuring chamber to calculate an analytical value.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial Application Field The present invention is directed to, for example, a spectrometer such as an autosampler, which is equipped with a table for accommodating a sample container containing a sample for measurement, a sample suction device, and a spectrophotometry device. The present invention relates to an analyzer, and particularly relates to an automatic spectrometer in which a spectrophotometer, such as an absorption photometer, a fluorometer, and a scattering photometer, is connected to an autosampler that stores a sample for measurement.

The present invention also relates to a spectroscopic analyzer for a small amount of sample, and particularly to an automatic spectroscopic analyzer capable of handling a large number of samples for test analysis, experimental analysis, and clinical analysis.

(b) Conventional technology For example, in an automatic spectrometer, measurement samples are collected from a plurality of sample containers each containing a measurement sample.
The sample suction nozzle sucks the sample, and then the sucked measurement sample is sequentially guided to the measurement section of a spectrophotometer equipped with a cell such as a flow cell, and the absorbance and fluorescence intensity of each sample are automatically measured. Measured.

(C) Problems to be Solved by the Invention However, in conventional automatic spectrometers, the distance between the sample suction nozzle and the flow cell is, for example, 70 to 80cm, due to the arrangement of the autosampler and the spectrometer.
m, and the problem is, for example, diameter III
connected by small tubes.

In such automatic spectrometers, during measurement, it is necessary to fill not only the flow cell but also the connection pipe mentioned above with the measurement sample, so the pipe line between the sample suction nozzle and the flow cell becomes a dead volume. There is. In addition, the sampling area from the sample suction nozzle to the flow cell is
It is contaminated each time by the previously measured sample, so in order to avoid the influence of contamination by the previously measured sample,
It requires at least several -1 measurement samples, for example,
This has become a problem as it has become difficult to conduct highly accurate analyzes of samples obtained in extremely small amounts, such as those related to biotechnology.

The present invention aims to solve the problem that conventional automatic spectrometers equipped with autosamplers require a large amount of sample to be measured, making it difficult to apply them to samples with small amounts. There is.

(d) Means for Solving the Problems The present invention aims to provide a spectroscopic analyzer, especially an automatic spectroscopic analyzer, equipped with an autosampler that enables spectroscopic analysis of a small amount of sample.

That is, the present invention provides a sample table having a plurality of sample container holding holes, a sample suction nozzle that is provided to be movable vertically and laterally with respect to the sample table, and a sample sucked into the sample suction nozzle. In a spectroscopic analyzer equipped with a spectrophotometer that optically measures a sample through a cell for spectroscopic analysis, the sample suction nozzle has at least a corresponding part of its corresponding side wall both formed of an optically transparent material. ,
They are located parallel to each other to form cells for spectroscopic analysis, and a lid member is provided above the cell portion to enable reciprocal movement between the sample suction position of the sample table and the measurement portion of the spectrophotometer. The spectrophotometer is provided with a nozzle insertion port in the measuring section of the spectrophotometer, and the lid member of the nozzle has a size that completely covers the nozzle insertion port. It's in the analyzer.

The sample suction nozzle of the present invention is capable of holding a liquid sample sucked from the sample suction nozzle in the sample suction nozzle, and then inserting it into a spectrophotometer to measure the spectrophotointensity of the liquid sample sucked and held. As shown, a part that can be used as a cell for spectroscopic analysis is formed in the nozzle part. In this cell part for spectroscopic analysis, the optically corresponding side wall of the nozzle part is made of an optically transparent material, such as a square cell, a cylindrical cell, etc., so that transmitted light and scattered light can be measured.
It can be formed into cells with various cross-sectional shapes.

In the present invention, the sample suction nozzle is connected to a suction source like a conventional sample suction nozzle.

When the suction source is formed by a syringe, it is possible to easily aspirate the measurement sample, expel the measured sample, and clean the inside of the sample suction nozzle.

The sample suction nozzle of the present invention includes:
It is inserted into the measurement chamber through the insertion port of the measurement chamber of the spectrophotometer. In order to prevent light from entering from the outside into the measurement chamber from the insertion port during measurement, the sample suction nozzle is provided with a lid member for sealing the insertion port above the cell section.

A lid member is provided on the suction tube above the cell section in order to shield the measurement chamber from light during photointensity measurement.

It is preferable that the lid member is provided with an elastic member on the contact side so that it can contact the outer wall surface of the measurement chamber and tightly cover the insertion port.

(E) Function In the present invention, the sample suction nozzle is provided with a cell part for spectrophotometric measurement and a light-shielding lid, so that, for example, a liquid sample sucked into the sample suction nozzle from a sample container placed in an autosampler can be The spectrophotometer can measure the spectrophotometric intensity of the aspirated liquid sample while it is being sucked into the sample suction nozzle, and the amount of sample required for spectroscopic analysis can be determined by This is determined by the capacity of the cell of the nozzle, and by reducing the capacity of the cell of the sample suction nozzle, it can be Spectrophotometric measurements of samples, etc. can be performed.

Therefore, according to the present invention, the amount of sample required for spectroscopic analysis is determined by the capacity of the cell section, regardless of the distance between the sample suction position of the sample suction nozzle and the spectroscopic measurement position. This makes it possible to reduce the amount of sample required for measurement without changing the size of the sample suction position of the sample suction nozzle and the spectrophotometry position, and also to change the amount of sample required for spectroscopic analysis. The arrangement of the autosampler and spectrophotometer can be determined arbitrarily.

(to) Examples Hereinafter, examples of embodiments of the present invention will be explained with reference to the accompanying drawings.
It is not limited in any way.

FIG. 1 is a schematic explanatory diagram of an example of the present invention applied to an automatic analyzer equipped with a turntable-type autosampler and an absorption photometry device, and FIG. FIG. 3 is a flow path diagram showing an example of a schematic flow path system of the embodiment shown in FIG. FIG. 3 is a partially enlarged side sectional view showing an example of the arrangement relationship between the spectrophotometer and the sample suction nozzle during measurement in the embodiment shown in FIG.

In the example shown in FIG. 1, an automatic spectrometer 1 is provided with an absorption photometer 4 at a position where a sample suction nozzle 3 of an autosampler 2 is movable. The sample suction nozzle includes a nozzle part 5, a cell part 6, and a suction part 7 (2nd Uf!i and Fig. 3).
A cell portion 6 is formed above the nozzle portion 5, and a suction portion 7 is formed above the cell portion 6. The upper part of the cell part 6 is protected by a covering member 8. This covering member 8 has a flange 9 formed on the lower side to form a lid 10, and the sample suction nozzle 3 having this covering member 8 is supported by a support arm 11 above.

On the other hand, the support arm 11 is held by a support shaft 13. The support shaft 13 is rotatably connected to a rotation device, is connected to a vertical movement device (both not shown) so as to be movable in the vertical direction, and is held on the base 12 so as to be rotatable and movable in the vertical direction. has been done. Therefore, the support arm 11 rotates and moves up and down as the support shaft 13 rotates and moves up and down.

As shown in FIG. 2, the sample suction nozzle 3 is connected at its upper suction section 7 to a conduit 15 to which a syringe 14 for sample suction is connected. The pipe line 15 is connected to the flow path switching valve 1
6, and this flow path switching valve 16
The flow path 18 is connected to a syringe 19 for cleaning liquid, and the remaining flow path 20 is connected to a conduit 23 whose tip is immersed in cleaning liquid 22 in a cleaning liquid container 21.

In this example, the base 12 of the autosampler 2 is provided with a sample stage 24 in the form of a turntable. This sample stage 24 is supported by a rotating shaft 25 connected to a driving device such as a stepping motor, and is driven intermittently and continuously at appropriate pitches.

The sample stage 24 is provided with a hole (not shown) for receiving a sample container, and a sample container 26 containing an analysis sample is placed in this hole to perform sampling.

Further, the base 12 is provided with a nozzle cleaning liquid discharge tank 27, and the sample suction nozzle 3 is connected to the cleaning liquid discharge tank 27.
The cleaning liquid used to clean the sample suction nozzle is discharged into this cleaning liquid discharge tank 27.

In this example, in the absorption photometer 4, a measurement chamber 31 including a light source section 29 and a measurement section 30 is formed in the housing 28.
A hole 33 for inserting a sample suction nozzle is formed through the hole 1 .

In FIG. 3, the sample suction nozzle 3 is provided with a quartz cell part 6 connected above a stainless steel nozzle part 5, and a suction part 7 connected to the upper part of the cell part 6. In this example, a covering member 8 is formed from the upper part of the cell part 6 to surround the suction part 7. In this example, the lower part of the covering member 8 forms a flange part 9 that protrudes to the periphery. The upper member 34 of the lid 1o is made of a material with relatively excellent corrosion resistance and mechanical strength, such as stainless steel or corrosion-resistant metal, which does not easily corrode or deform. 35 is made of an elastic material in order to make close contact and sufficiently perform the light shielding function.

A hole 33 for inserting the sample suction nozzle 3 formed in the upper wall 32 of the housing 28 of the spectrophotometer 4 is formed with an annular support portion 36 projecting inward, so that the sample suction nozzle 3 can be inserted into the measurement chamber. 31, the measurement position can be determined by confirming that the lower end 37 of the covering member 8 is in contact with the upper surface of the annular support 36.

The absorption photometer 4 is provided with a light source side window 38 and a measurement side window 39 facing each other so as to sandwich the measurement chamber 31 therebetween.

In this example, since the automatic spectroscopic analyzer 1 is configured as described above, the support shaft 13 is rotated to move the sample suction nozzle 3 to the sample suction position 1f40.
Move the support shaft 13 downward to lower the sample suction nozzle 3, move the screw 41 of the syringe 14 to the suction side, and transfer the sample from the sample container 26 located at the sample suction position 40 to the sample suction nozzle. Aspirate within 3. After sucking the sample into the sample suction nozzle 3, move the support shaft 13 upward to raise the sample suction nozzle 3.Next, rotate the support shaft 13 to raise the sample suction nozzle 3.
Move it above the insertion hole 33 of the spectrophotometer 4.

When the sample suction nozzle 3 has moved above the insertion hole 33, the support shaft 13 is moved downward, the sample suction nozzle 3 is inserted into the insertion hole 33, and the sample suctioned and held in the cell part 6 is removed. The measured take is sent from the absorbance measurement room to a computer and an analytical value is determined.

After completing the measurement, the sample suction nozzle 3 is moved onto the cleaning liquid discharge tank 27 by rotation of the support shaft 13.

Meanwhile, during this period, the rotor 42 of the flow path switching valve 16 is
Rotate 90 degrees counterclockwise from the position shown in FIG. 2 and move the piston 43 of the cleaning liquid syringe 19 to the suction side.
The cleaning liquid 22 in the cleaning liquid container 21 is sucked into the cleaning liquid syringe 19.

When the sample suction nozzle 3 that has completed the measurement moves onto the cleaning liquid discharge tank 27, the rotor 42 of the flow path switching pulp 16
180 degrees clockwise and insert the cleaning liquid syringe 1.
9 and the piston 41 of the syringe 14 for sample suction are both moved to the discharge side, and the syringe 14
The sample and cleaning liquid in the sample suction nozzle 3 are sent to the sample suction nozzle 3 to clean the inside of the sample suction nozzle 3. The washed cleaning waste liquid is discharged into the cleaning liquid discharge tank 27.

In this way, in this example, the absorbance can be measured while the sample is suctioned and held in the sample suction nozzle 3, so regardless of the positions of the spectrophotometer 4 and the autosampler 2, A sample of the capacity of the cell portion 6 of the nozzle 3 can be used to measure the absorbance. Therefore, by reducing the capacity of the cell section 6,
Analysis using a small amount of sample becomes possible.

In this example, the cell portion is formed in a bulging shape, but it may be in any shape as long as it can measure spectrophotointensity.

In this example, absorbance measurement is performed, but depending on the purpose, the measurement surface relative to the light source can be changed to perform fluorescence photometry, scattered light photometry, etc.

In this example, the cell part is made of quartz, but for measurements in the ultraviolet and visible light regions, it can be made of Pyrex glass, and a vacuum glass capillary can also be used.

(G) Effects of the Invention The present invention provides, for example, a sample suction nozzle of an autosampler that is provided with a cell section for spectrophotometry, and a liquid sample placed in the autosampler is sucked into the sample suction nozzle.
While the aspirated liquid sample is held in the sample suction nozzle,
Since spectrophotometers can now measure spectrophotometers, there is no dead volume caused by the distance between the spectrophotometers and the autosampler, compared to conventional spectrophotometers. The autosampler and autosampler can be freely arranged without being constrained by the sample capacity, etc.

Moreover, according to the present invention, it is possible to perform spectroscopic analysis of a small amount of sample, which was difficult to do with conventional devices, and it is useful in many fields because it enables automatic spectrophotometric measurements.

[Brief explanation of the drawing]

FIG. 1 is a schematic explanatory diagram of an example of the present invention applied to an automatic analyzer equipped with a turntable-type autosampler and an absorption photometer, and FIG. FIG. 3 is a flow path diagram illustrating an example of a schematic wave path system of the illustrated embodiment. FIG. 3 is a partially enlarged side sectional view showing an example of the arrangement relationship between the spectrophotometer and the sample suction nozzle during measurement in the embodiment shown in FIG. Regarding the symbols in the figure, 1 is the automatic spectrometer 2 is the autosampler, 3 is the sample suction nozzle, 4 is the spectrophotometer,
5 is a nozzle part, 6 is a cell part, 7 is a suction part, 8 is a covering member, 9 is a collar part, 10 is a lid part, 11 is a support arm, 12 is a base, 13 is a support shaft, 14 and 19 are syringes , 15 and 23 are pipes, 16 is a flow path switching valve, 21 is a cleaning liquid container, 22 is a cleaning liquid, 24 is a sample stage, 25 is a rotating shaft, 26 is a sample container, 27 is a cleaning liquid discharge tank, 28 is a housing, 2
9 is a light source part, 30 is a measurement part, 31 is a measurement chamber 32 is an upper wall, 33 is an insertion hole, 34 is an upper member, 35 is a lower member, 3
6 is an annular support part, 37 is a lower end of the covering member, 38 is a light source S window, 39 is a measurement side window, 40 is a sample suction position, 41
43 is a piston, and 42 is a rotor.

Claims (1)

[Claims] A sample table provided with a plurality of sample container holding holes, a sample suction nozzle provided to be movable vertically and laterally with respect to the sample table, and a cell for spectroscopic analysis of the sample sucked into the sample suction nozzle. In a spectroscopic analyzer comprising a spectrophotometer that measures optically through A cell for spectroscopic analysis is formed, and a lid member is provided above the cell part so as to be movable back and forth between the sample suction position of the sample table, the measurement part of the spectrophotometer, and the nozzle cleaning part. A spectroscopic analysis characterized in that the measurement section of the spectrophotometer is provided with a nozzle insertion port, and the lid member of the nozzle has a size that completely covers the nozzle insertion port. Device.