JP2002168842A - Liquid chromatograph and analyzing method using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inexpensive system in which a sample introducing device is commonly used in the case of parallelly processing sample analysis through the use of a plurality of liquid chromatographs. SOLUTION: The system provided with a plurality of pumps and columns is constructed, and the sample introducing device is one. By performing switching operation on a channel switching valve, a pump and a column selected from among the plurality of pumps and columns are connected to the sample introducing device.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid chromatograph, and more particularly to a technique for performing a plurality of sample analyzes in parallel.

[0002]

2. Description of the Related Art Conventionally, in one-system liquid chromatograph, generally, after one sample analysis is completed, the next sample analysis is performed.

[0003] When a sample analysis is performed in parallel with high throughput, it is necessary to prepare a plurality of liquid chromatographs.
Conventionally, in order to correspond to each liquid chromatograph, the same number of sample introduction devices as the liquid chromatograph have been required.

However, when performing sample analysis at a high throughput, it is necessary to prepare the same number of sample introduction devices as for the liquid chromatograph in order to support each liquid chromatograph. Become.

The prior art relating to liquid chromatography is disclosed in, for example, JP-A-2-45759 and JP-A-2-45759.
No. 96657, JP-A-4-190159 and the like.

[0006]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an inexpensive system in which a plurality of liquid chromatographs are used in parallel to perform sample analysis, and a common sample introduction device is used. .

[0007]

The object of the present invention is to provide a system having a plurality of pumps and columns by using a single sample introduction device and switching a flow path switching valve. This is achieved by connecting a pump and a column selected from the above to the sample introduction device.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the drawings, in the case of a chromatograph 2 system.

FIG. 1 shows a system configuration according to the present embodiment.

[0010] The pump 1 of the system (1) and the column 3 of the system (1) are connected to the sample introduction device 7, and the pump 2 of the system (2) and the column 4 of the system (2) are connected to the bypass flow of the system (2). The flow path connected to the line 11, the pump 1 of the system (1) and the column 3 of the system (1) are connected to the bypass flow path 10 of the system (1), and the pump 2 and the system (2) of the system (2) are connected. The flow path connecting the column 4 to the sample introduction device 7 is switched by a first switching valve 8.
And by the second switching valve 9.

First switching valve 8 and second switching valve 9
Is switched to the flow path connected to the pump 1 of the system (1) and the column 3 of the system (1), the mobile phase 12 sent from the pump 1 is supplied from the first switching valve 8 The liquid is sent to the sample introduction device 7.

A sample is introduced into the mobile phase 12 from the sample introduction device 7, and the introduced sample passes through the second switching valve 9 together with the mobile phase 12, is separated in the column 3, and is detected by the detector 5.

At this time, the mobile phase 13 sent from the pump 2 of the system (2) passes through the first switching valve 8, the bypass flow path 11 of the system (2), and the second switching valve 9, and
The liquid is sent from the column 4 of the system (2) to the detector 6 of the system (2).

First switching valve 8 and second switching valve 9
Is switched to the flow path connected to the pump 2 of the system (2) and the column 4 of the system (2), the mobile phase 13 sent from the pump 2 is supplied from the first switching valve 8 The liquid is sent to the sample introduction device 7.

A sample is introduced from the sample introduction device 7 into the mobile phase 13, and the introduced sample passes through the second switching valve 9 together with the mobile phase 13, is separated in the column 4, and is detected by the detector 6.

At this time, the mobile phase 12 sent from the pump 1 of the system (1) passes through the first switching valve 8, the bypass flow path 10 of the system (1), and the second switching valve 9.
The liquid is sent from the column 3 of the system (1) to the detector 5 of the system (1).

FIG. 2 shows a flow path in which the sample introduction device 7 is incorporated between the pump 1 of the system (1) and the column 3 of the system (1).

In the first switching valve 8, the port 8a
And port 8b, and port 8c and port 8d are connected.

In the second switching valve 9, the port 9a
And port 9b, and port 9c and port 9d are connected.

The mobile phase 12 sent from the pump 1 of the system (1) moves from the port 8a of the first switching valve 8 to the sample introducing device 7 through the port 8b. The sample introduction device 7 introduces a sample into the mobile phase 12. The introduced sample, together with the mobile phase 12, is supplied to the port 9b of the second switching valve 9.
Through port 9a and into column 3 of system (1), where it is separated.

At this time, the mobile phase 13 sent from the pump 2 of the system (2) is connected to the port 8 of the first switching valve 8.
From the port c through the port 8d, the system moves to the column 4 of the system 2 via the bypass channel 11 of the system (2) and the port 9d of the second switching valve 9 via the port 9c.

FIG. 3 is a flow chart in which the first switching valve 8 is rotated by 36 degrees clockwise and the second switching valve 9 is rotated by 36 degrees counterclockwise from the state of FIG.

The mobile phase 12 sent from the pump 1 of the system (1) passes through the port 8a to the port 8e of the first switching valve 8, passes through the bypass flow path 10 and the port 9e of the second switching valve 9, The solution is sent to column 3 of system (1) via 9a.

At this time, the mobile phase 13 sent from the pump 2 of the system (2) is connected to the port 8 of the first switching valve 8.
The liquid is sent to the column 4 of the system (2) via the bypass flow path 11 and the port 9d of the second switching valve 9 through the port 9d through the port 8d.

The flow path shown in FIG. 3 is a flow path in which both the flow paths of the system (1) and the system (2) are separated from the sample introduction device 7, and the flow path is stabilized before the sample analysis, and the solvent is replaced. It is used in such cases, but is not always necessary.

FIG. 4 is a flow chart in which the first switching valve 8 is rotated clockwise by 36 ° and the second switching valve 9 is rotated counterclockwise by 36 ° from the state of FIG.

The mobile phase 12 sent from the pump 1 of the system (1) passes through the ports 8a to 8e of the first switching valve 8, passes through the bypass flow path 10 and the port 9e of the second switching valve 9, Move to column 3 of system (1) via 9a.

The mobile phase 13 sent from the pump 2 of the system (2) moves from the port 8c of the first switching valve 8 to the sample introducing device 7 through the port 8b. The sample introduction device 7 introduces a sample into the mobile phase 13. The introduced sample, together with the mobile phase 13, is supplied to the port 9b of the second switching valve 9.
Through port 9c and into column 4 of system (2) for separation.

That is, when introducing a sample into the system (1), the flow path is switched to the flow path shown in FIG. 2, and when introducing a sample into the system (2), the flow path is switched to the flow path shown in FIG.

Next, the flow of the sample analysis of the present invention using the above configuration will be described with reference to FIGS.

FIG. 5 shows the flow of sample analysis according to the prior art when the gradient analysis method is used.
Analysis of sample 1 → equilibration → introduction of sample 2 → analysis of sample 2 → equilibration → introduction of sample 3 → analysis of sample 3 → equilibration → introduction of sample 4 →
This indicates that the analysis of sample 4 → equilibration... And the sample analysis are performed in series.

Here, the balancing will be described. Equilibration refers to the gradient elution method in which the mixing ratio of the mobile phase (eluent) is changed with time.In order to perform the next analysis, the condition of the column etc. is returned to the initial solvent condition after the analysis is completed. It means until you return to the beginning.

However, even if the conditions are restored, it takes some time for the solvent in the column to be replaced. The time required for the equilibration varies depending on the analysis conditions and the like, but usually requires about 10 to 20 minutes. Since the analysis itself is usually about 30 to 60 minutes, about の of the analysis time is extra time for this equilibration. Therefore, in order to perform high-throughput analysis, it is necessary to shorten the equilibration time.

FIG. 6 is a diagram showing the flow of sample analysis according to one embodiment of the present invention.

First, the first switching valve 8 and the second switching valve 9 are rotated so that the sample introduction device 7 is connected to the system 1.

The sample 1 is introduced from the sample introduction device 7 into the system (1). After the analysis is completed in the system (1), the first switching valve 8 and the second switching valve 9 are rotated at the time of shifting to equilibration, and the sample introduction device 7 is connected to the system (2). Sample 2 from the sample introduction device 7 is a system
Will be introduced. After the analysis is completed in the system (2), the first switching valve 8 and the second switching valve 9 are switched when equilibrium is started, and the sample introduction device 7 is connected to the system (1). Thereafter, by repeating the above operation, the analysis is continuously performed.

According to this embodiment, the next sample can be introduced at the time of starting the equilibration, and the time required for the equilibration can be omitted.

FIG. 7 is a diagram showing a flow of sample analysis according to another embodiment of the present invention.

First, the first switching valve 8 and the second switching valve 9 are rotated so that the sample introduction device 7 is connected to the system (1).

The sample 1 is introduced from the sample introduction device 7 into the system (1). The mobile phase 12 into which the sample 1 has been introduced is supplied to the second switching valve 9 (port 9) on the downstream side of the sample introduction device 7.
After a lapse of time passing through a), the first switching valve 8 and the second switching valve 9 are rotated to connect to the system (2). Sample 2 from the sample introduction device 7 is a system
Will be introduced. After the analysis of the sample 2 is completed and the equilibration is completed, the first switching valve 8 and the second switching valve 9 are rotated so as to be connected to the system (1). Sample introduction device 7
The sample 3 is introduced into the system 1. Thereafter, by repeating the above operation, the analysis is continuously performed.

According to this embodiment, the system (1) and the system (2) can start the analysis almost simultaneously. Therefore, the same analysis as in a system in which two sample introduction devices 7 are installed can be performed, which contributes to a further reduction in time when performing high-throughput analysis.

As described above, according to the embodiment of the present invention, when a plurality of liquid chromatographs are used for parallel processing of sample analysis, an inexpensive system that shares a sample introduction device is provided. be able to.

In the embodiment shown in FIG. 7, the system (1)
Of the sample 1 in the system (2) → the analysis of the sample 2 in the system (2) → end of the equilibration process slightly after the equilibration process, but the analysis of the sample 1 in the system (1) → the equilibrium Analysis of sample 2 in the system (2) rather than the conversion treatment →
When the equilibration process is completed early, the sample introduction device 7 is randomly connected to the systems (1) and (2), for example, by analyzing the sample 3 using the system (2) and performing the equilibration process. It is also possible to introduce a sample.

In the above embodiment, an example in which equilibration is required, such as a gradient elution method, has been described. However, even when an isocratic elution method that does not require equilibration is employed, the same sample analysis, ie, ( 1) After the selected system has completed the sample analysis, the sample introduction device is switched and connected to another liquid chromatograph, or (2) the sample is introduced into the mobile phase of the selected system, and the sample is introduced. After a lapse of time when the mobile phase has passed through the liquid sending valve on the downstream side of the sample introduction device, the sample analysis can be performed by switching the sample introduction device to another system.

When the same sample is analyzed under different conditions, conventionally, it is necessary to replace the liquid of the system according to the separation conditions or to prepare a required number of systems according to the separation conditions. However, according to the present embodiment, it is possible to analyze the same sample under different conditions by changing the elution conditions of the system (1) and the system (2) and introducing the sample as in the previous embodiment. it can.

Further, the flow path configuration of the switching valves 8 and 9 shown in the above embodiment is an example, and another flow path configuration may be used.

[0047]

According to the present invention, it is possible to provide an inexpensive system that shares a sample introduction device when sample analysis is performed in parallel using a plurality of liquid chromatographs.

The fact that a sample can be introduced using a single sample introduction device is advantageous when a sample is set easily and high-throughput analysis is performed in a short time.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram showing an embodiment of the present invention.

FIG. 2 is a view showing a flow path in which the sample introduction device 7 in FIG. 1 is incorporated between the pump 1 of the system (1) and the column 3 of the system (1).

In FIG. 2, the first switching valve 8 is rotated clockwise by 36 °, and the second switching valve 9 is rotated counterclockwise by 36 degrees.
FIG. 7 is a flow chart rotated by °.

FIG. 4 is a view showing a state in which the first switching valve 8 is rotated clockwise by 36 ° and the second switching valve 9 is rotated counterclockwise by 36 degrees in FIG.
FIG. 4 is a flow path diagram rotated by °.

FIG. 5 is a diagram showing a flow of sample analysis according to a conventional technique.

FIG. 6 is a diagram showing a flow of sample analysis according to one embodiment of the present invention.

FIG. 7 is a diagram showing a flow of a sample analysis according to another embodiment of the present invention.

[Description of Signs] 1 ... pump, 2 ... pump, 3 ... column, 4 ... column,
5 Detector, 6 Detector, 7 Sample introduction device, 8 First
Switching valves, 8a to 8e: ports of the first switching valve 8,
9: second switching valve, 9a to 9e: port of second switching valve 9, 10: bypass flow path, 11: bypass flow path, 1
2 mobile phase, 13 mobile phase.

Claims (7)

[Claims] 1. A liquid chromatograph comprising: a plurality of pumps for sending a mobile phase; a sample introduction device for injecting a sample into the mobile phase; and a plurality of columns for separating the sample. A liquid chromatograph comprising: a pump and a column selected from the plurality of pumps and columns connected to the sample introduction device by a switching operation of the flow path switching valve. 2. The liquid chromatograph according to claim 1, wherein the sample pump is connected to another pump and column after the selected pump and column have completed the sample analysis. 3. The lapse of time during which a sample is introduced into a mobile phase to which a selected pump sends liquid, and the mobile phase into which the sample has been introduced has passed a flow path switching valve on the downstream side of a sample introduction device according to claim 1. Then, a liquid chromatograph configured to connect the sample introduction device to another pump and column. 4. The flow path switching valve according to claim 1, wherein the flow path switching valve is a first flow path switching valve that connects the pump and the sample introduction device, and a second flow path that connects the column and the sample introduction device. A liquid chromatograph comprising a path switching valve. 5. The flow path according to claim 4, wherein a flow path from the pump to the column is formed between the first flow path switching valve and the second flow path switching valve without passing through the sample introduction device. A liquid chromatograph comprising a bypass flow path. 6. A plurality of pumps for feeding a mobile phase, a sample introduction device for injecting a sample into the mobile phase, a plurality of columns for separating a sample, and the selected pump and the column are connected to the sample introduction device. An analysis method using a liquid chromatograph having a flow path switching valve connected to the pump, wherein the flow path switching valve selects the pump and the column, and the selected pump-sample introduction device-selected A first flow path composed of a column is formed and analysis is performed. After the analysis using the first flow path is completed, the flow path switching valve is switched to provide a new pump-sample introduction device-new column An analysis method using a liquid chromatograph, wherein the analysis is performed using a second flow path comprising: 7. A plurality of pumps for sending a mobile phase, a sample introduction device for injecting a sample into the mobile phase, a plurality of columns for separating a sample, and one of the pumps connected to the sample introduction device. An analysis method using a liquid chromatograph comprising a first flow path switching valve and a second flow path switching valve for connecting one of the columns to the sample introduction device, comprising: A first flow path including a flow path switching valve, a sample introduction device, a second flow path switching valve, and a column is formed to perform analysis, and the sample introduced from the sample introduction device is switched to the second flow path. After passing through the valve, the first and second flow path switching valves are switched, and a new pump, a first flow path switching valve, a sample introduction device, a second flow path switching valve, and a new column including a new column are formed. Characterized by performing analysis using two channels Analysis method using the body chromatograph.