JPH0425655Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention relates to a liquid chromatograph device configured to introduce a sample using a degassed buffer liquid.

[Prior Art] When sampling a sample in a liquid chromatograph apparatus, as shown in FIG. , and a small amount of sample suction buffer liquid is aspirated by the sampling pump 3. 4 is a sampling valve, and as shown in FIG. 7, the sampling valve includes a rotating portion R provided with a sampling tube ST, and a fixed portion provided with communicating holes S ₁ , S ₂ , S ₃ , and S ₄ . The rotating part is rotationally driven by a drive mechanism not shown so that any two openings of the sampling tube and the opening of the communication hole on the side that are in contact with the rotating part coincide with each other. The other opening a of the communication hole _S1 is connected to the sampling pump 3, the other opening b of the communication hole _S2 is connected to the pipette drive mechanism 1,
The other opening c of the communication hole _S3 is connected to the buffer liquid supply system (hereinafter referred to as buffer supply system) of the separation column.
The other openings d of S ₄ are respectively connected to the separation column system. Incidentally, FIG. 6 shows a state in which the opening of the sampling tube ST is connected to the openings a and b.
Then, the pipette P is inserted into the sample container 5 by the operation of the pipette drive mechanism 1, and a predetermined amount of the sample is aspirated by the sampling pump 3.
Then, the pipette P is inserted into the buffer container 2 again by the operation of the pipette drive mechanism 1, and a small amount of buffer liquid is aspirated by the sampling pump 3. After that, the pipette P is not inserted into any container. The pump 3 is activated to move the liquid in the pipette P to the sampling tube ST in the sampling valve. in this case,
As shown in FIG. 8, a sample S is located at the center of the sampling tube ST of the sampling valve 4, and these liquids are moved so that the sample is sandwiched between buffer liquids B. Furthermore, the buffer liquid is filled outside the sampling tube ST so that no space is left inside the tube. This is because if there is a space inside the ST, when the ST is connected to the separation column line, the space inside the ST will be collapsed by the high pressure on the separation column side, and the rate of liquid delivery to the separation column will be reduced. This is because, as a result, the baseline of the analysis spectrum changes.
Then, the sampling valve 4 is arranged so that the opening of the sampling tube ST is connected to the openings c and d.
Rotate the rotating part R of. Due to this rotation, the sample and buffer liquid are valve-cut at both ends of the sampling tube ST, and sampling of the sample is completed. The sample and buffer liquid in the sampling tube ST are pushed into the separation column 8 together with the buffer liquid for column development from the buffer container 7 by the action of a buffer liquid pump (hereinafter referred to as buffer pump) 6 that constitutes a buffer supply system. It can be done. The sample components separated from the separation column are mixed with reagents from a reagent delivery system 10 in a mixer 9. Then, the reaction solution is sent to the cell 11, where a concentration corresponding to the concentration of the reaction solution is detected by the detector 12, and the concentration corresponding to the concentration of the reaction solution is detected by the recorder 13.
will be displayed. L is a light source, and 14 and 15 are waste liquid tanks.

The reason why the buffer solution is added before and after the sample instead of other liquids is to prevent the concentration (PH value) of the buffer solution, which is poured into the separation column together with the sample in the later process, from changing. For some reason, the buffer containers 2 and 7 in Figure 6
contain a buffer solution of the same concentration.

Also, as another example of sampling, in FIG. 6 above, without using the buffer container 2, directly,
As shown in FIG. 9, the sample S is sucked and moved from the sample container 5 by the pipette P so that the sample is accommodated on both sides of the sampling tube ST of the sampling valve 4, and in this state, the rotating part of the sampling valve Another method is to rotate R and cut the valve.

[Problem to be solved by the invention] In the former sampling example, the inner diameter of the sampling tube ST or the conduit connecting the pipette and the sampling tube should be kept as small as possible to prevent the sample and buffer liquid contained inside from diffusing into each other. The smaller one is selected. However, if the inner diameter is small, the resistance to the liquid will be large, and bubbles will easily occur in the buffer liquid transferred into the sampling tube ST. When the bubbles are generated, the flow rate of the buffer liquid is delayed due to absorption of pressure by the bubbles, or the flow rate suddenly increases due to the bursting of the bubbles, resulting in components eluted from the separation column 8. The flow velocity changes, and a noise peak is recorded on the baseline of the recorder 13.

Furthermore, in the latter sampling example, the amount of sample to be sampled cannot be arbitrarily set, and if a different amount is to be sampled, the sampling valve or sampling tube must be replaced. However, such replacement is difficult.

The present invention is aimed at solving such problems.

[Means for solving the problem] The present invention attempts to introduce the degassed buffer liquid into the sampling tube before the sample, and in this case, a deaerator is placed between the pipettes of the device. It is difficult to do so in terms of sample dispersion, and it is also difficult to install a pipette between the pipette drive mechanism and the sampling valve because the distance between them must be as short as possible in order to increase the accuracy of the sampling amount. , and buffer liquid that has been previously degassed elsewhere may be placed in a buffer container and this buffer liquid may be aspirated, but this may be fine at first, but as time passes, the buffer liquid in the buffer container may deteriorate. Taking into consideration that the deaeration effect would be lost, it was constructed as follows.

That is, a pipette for sample collection, a separation column, a sampling pump, a first degassing means for degassing the buffer liquid for sample suction, and a second degassing means for degassing the buffer liquid for column development. a degassing means, and a sampling valve for connecting the pipette and the sampling pump or connecting the second degassing means and the separation column by switching an internal sampling tube;
a flow path switching valve for switching and connecting the first degassing means or the sampling tube of the sampling valve to the sampling pump; and a flow path switching valve for connecting the first degassing means or the sampling tube of the sampling valve, and passing the buffer liquid from the second degassing means through the sampling tube of the sampling valve. and a pump for sending liquid to the separation column.

[Example] FIG. 1 is a schematic diagram of a liquid chromatograph apparatus showing an example of the present invention.

The same numbers and symbols used in FIG. 6 are the same components. 4 in the figure is the seventh
The sampling valve has the configuration as shown in the figure, but the difference is that in Figure 7, it is the sampling pump that is connected to the other opening a of the communicating hole _S1 , but in Figure 1, the flow path switching Opening a ₁ of valve 16
It is connected to As shown in Fig. 3, the flow path switching valve is a rotating part provided with a flow path _F1 .
Fixed part with R ₁ and communicating holes S ₁₁ , S ₁₂ , S ₁₃
The rotating part is rotationally driven by a drive mechanism not shown in the drawings so that any two openings of _the flow path _F1 and the opening of the communication hole on the side that are in contact with the rotating part coincide with each other. be done. As described above, the other opening a ₁ of the communication hole S ₁₁ is connected to the sampling valve 4, the other opening b ₁ of the communication hole S ₁₂ is connected to the other opening c 1 of the communication hole S 13, and the other opening c ₁ of the communication hole S ₁₃ is connected to the sampling pump 17. One opening h ₁ of the chamber is connected to the buffer container 18 . A buffer liquid for sample suction is stored in the buffer container 18, and a first deaerator 19 is installed between the buffer container 18 and the opening _c1 of the flow path switching valve 16. has been done. The concentration of the buffer liquid contained in the buffer container 18 is the same as that of the buffer liquid contained in the buffer container 7. The degassing device is as shown in FIG.
It consists of a heating tube 20 and an air trap 21. The heating tube is heated by a heater 22, and the conduit
The liquid entering the heating tube 20 from T ₁ is heated here and separated into a liquid portion and a gas portion. Then, the separated liquid and gas portions enter the air trap 21 from the conduit _T2 , where the gas portion is trapped and passes through the liquid portion length conduit _T3 . The other opening _h2 of the pump chamber of the sampling pump 17 is provided with a flow path switching valve 23 similar to the flow path switching valve shown in FIG.
Apertures a and ₂ are connected. Opening of the switching valve
A water container 24 is connected to _b2 . Further, the opening _c2 of the switching valve is plugged with a plug. A second deaerator 25 as shown in FIG. 2 is provided between the buffer container 7 and the buffer pump 6.
In addition, 26 is a waste liquid tank.

In such an apparatus, first, as shown in FIG. 1, the sampling channel system is cleaned. In this case, the flow path F ₂ of the flow path switching valve 23 is opened a ₂ , b ₂
The flow path F ₁ of the flow path switching valve 16 is set to a position where it does not connect to any of the openings a ₁ , b ₁ , and c ₁ , and the sampling tube ST of the sampling valve 4 is switched to the openings a and b. Further, the pipette P is driven by the pipette drive mechanism 1 so as to be positioned within the waste liquid tank 26. In this state, water is sucked up from the water container 24 by the sampling pump 17. Then, the flow path switching valve 23
At the same time, the flow path F ₂ of the flow path switching valve 16 is switched to the openings a ₂ and c ₂ as shown by the dotted line, and the flow path F ₁ of the flow path switching valve 16 is opened.
After switching to a ₁ and b ₁ , the sampling pump 17
The water is transferred to the flow path F ₁ of the flow path switching valve, the sampling tube ST of the sampling valve 4,
The liquid is poured into pipette P and discharged into waste liquid tank 26.

Next, a buffer liquid is set in the channel. In this case, as shown in FIG. 4a, the flow path switching valve 16
Flow path F ₁ is switched to openings b ₁ and c ₁ . In this state, the buffer liquid in the buffer container 18 is introduced into the flow path between the deaerator 19 and the sampling pump 17 via the deaerator 19 by the sampling pump 17 . The amount of buffer liquid is determined in consideration of the amount of sample to be accommodated in the sampling tube ST of the sampling valve, and is controlled by the operating amount of the sampling pump 17.

Next, the buffer liquid is transferred to the sampling valve 4.
into the sampling tube ST. In this case, as shown in FIG. 4b, the switching valve 1
The flow path F ₁ of No. 6 is switched to the openings a ₁ and b ₁ . In this state, the sampling pump 17 causes the buffer liquid in the channel to flow into the sampling tube ST and pipette P of the sampling valve 4.

Next, the sample is set in the sampling tube ST as shown in FIG. 4c (sampling).
In this case, the pipette drive mechanism 1 is operated so that the pipette P is inserted into the sample container 5. In this state, the sampling pump 17
The sample is sucked up from the sample container 5 and moved into the sampling tube ST of the sampling valve 4. In this case, the amount of sample accommodated in the sampling tube is controlled by the amount of operation of the sampling pump 17. or,
Inside the sampling tube, as shown in Fig. 5, part B of the buffer liquid is placed at the tip, and the sample S is placed in the other part of the sampling tube other than the tip and on the outside of the tube. The amount of operation of the sampling pump 17 is controlled so that the sampling pump 17 protrudes (about 1 to several microns). Then, as shown in Fig. 4d, the sampling valve 4 is connected so that the sampling tube ST is connected to the openings c and d.
Switch the rotating part and cut the sample into a valve. This completes the sampling process.

The sample is analyzed in the following manner. As shown in FIG. 4d, the sample and buffer liquid in the sampling tube ST are transferred to the separation column 8 together with the buffer liquid from the buffer container 7 that has passed through the deaerator 25 by the action of the buffer pump 6 forming the buffer supply system. being swept away inside. The sample components separated from the separation column are mixed with reagents from a reagent delivery system 10 in a mixer 9. Then, the reaction liquid is sent to the cell 11, and a concentration corresponding to the concentration of the reaction liquid is detected by the detector 12 and displayed on the recorder 13.

In the above embodiment, separate buffer containers 7 and 18 were used, but a single container may also be used. Further, the deaerator is not limited to the one shown in FIG.

[Effects of the invention] According to the invention, since the sample is always guided into the sample tube of the sampling valve by the degassed buffer liquid, air bubbles are not generated in the tube, so the separation The amount of components eluted from column 8 becomes constant over time,
No peaks as noise are recorded on the baseline of the sample components recorded on the recorder 13. Furthermore, the amount of sample to be sampled can be set arbitrarily and accurately without replacing the sampling valve or sampling tube.
In addition, the amount of sample loss can be minimal.

Furthermore, in the present invention, the buffer liquid sucked prior to sampling is sucked by the sampling pump without using a separate pump, so the entire apparatus is simplified.

[Brief explanation of the drawing]

Figure 1 shows one embodiment of the present invention, Figure 2 shows an embodiment of the present invention.
Figures 4 and 3 are partially detailed views thereof, Figures 4 a to d and 5 are diagrams to supplement the explanation of the operation of the device, and Figure 6 is a schematic diagram of a conventional liquid chromatograph device. Figure 7 is a detailed diagram of a part of it, Figures 8 and 9.
The figure is a diagram to supplement the explanation of the operation of the device. 1... Pipette drive mechanism, 4... Sampling valve, ST... Sampling tube, 5...
Sample container, 6... Buffer liquid pump, 7... Buffer liquid container, 8... Separation column, 9... Mixer,
10... Reagent feeding system, 11... Cell, 12... Detector, 13... Recorder, 16, 23... Channel switching valve, F ₁ , F ₂ ... Channel, 17... Sampling pump , 18... Buffer liquid container, 19,2
5...First and second deaerators, 24...Water container,
26...Waste liquid tank.

Claims (1)

[Scope of utility model registration request] A pipette for sample collection, a separation column, a sampling pump, a first degassing means for degassing the buffer liquid for sample suction, and a second degassing means for degassing the buffer liquid for column development. means, a sampling valve for connecting the pipette and the sampling pump or connecting the second degassing means and the separation column by switching a sampling tube therein; A flow path switching valve for switching and connecting the deaeration means or the sampling tube of the sampling valve, and a flow path switching valve for sending the buffer liquid from the second deaeration means to the separation column through the sampling tube of the sampling valve. A liquid chromatography device consisting of a pump.