KR20180002985A - Apparatus to inject sample gas of fixed quantity into gas chromatograph - Google Patents

Abstract

The present invention relates to an apparatus for injecting a fixed amount of sample gas for a gas chromatograph, which is provided in a gas chromatograph to inject a fixed amount of sample gas into a column. The apparatus of the present invention comprises: a first three-way valve including a first inlet connected to a carrier gas inlet path into which carrier gas is introduced, a second inlet located adjacent to the first inlet, and a third inlet located adjacent to the first and second inlets, respectively and connected to the column through the carrier gas inlet path; a second three-way valve including a fourth inlet connected to the second inlet, a fifth inlet located adjacent to the fourth inlet and connected to a sample gas inlet path into which sample gas is introduced, and a sixth inlet located adjacent to the fourth and fifth inlets, respectively; a sample loop connected to the sixth inlet and filled with sample gas introduced through the sample gas inlet path; a third three-way valve including a seventh inlet connected to the sample loop, an eighth inlet located adjacent to the seventh inlet and connected to a sample gas outlet path from which the sample gas introduced through the sample gas inlet path is discharged, and a ninth inlet located adjacent to the seventh and eighth inlets, respectively and connected to the carrier gas inlet path between the third inlet and the column; and a control unit controlling the first, second, and third three-way valves to be opened and closed such that the sample gas filled inside the sample loop is injected into the column.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for injecting a sample gas for a gas chromatograph,

The present invention relates to a sample gas metering device for a gas chromatograph configured to inject a predetermined amount of a sample gas into a column of a gas chromatograph using three three way valves.

The gas chromatograph separates the sample gas composed of various kinds of gas components by using the concentration equilibrium of the gas components. When the sample gas is moved to the column for separating the gas components, the gas (that is, the carrier gas ). ≪ / RTI > However, when the sample gas is injected into the column of the gas chromatograph, if the amount of the sample gas injected changes, the amount of the gas components constituting the sample gas changes. As a result, qualitative analysis or quantitative analysis It is difficult to be precisely done. Therefore, in order to improve the analysis accuracy of the sample gas composed of various kinds of gas components, it is required to inject the sample gas into the column of the gas chromatograph in a quantitative manner.

Conventionally, a method of manually injecting a sample gas into a gas chromatograph using a syringe has been mainly adopted. However, such a manual injection method has a problem in that the precision of injecting the sample gas is greatly reduced due to the time of injecting the sample gas, the pressure applied to the injector, and the septum aging of the injector.

On the other hand, in order to solve such a problem, Patent Document 1 discloses a gas chromatograph in which an exhaust passage is provided in a connection pipe connected to a column outlet of a gas chromatograph, an exhaust means is connected to the exhaust passage through an opening / closing valve, It is disclosed that the gas detector and the resistance pipe are provided in the exhaust flow path between the means and the amount of solvent in the sample is measured by the gas detector to correct the quantitative value of the component to be analyzed, .

Japanese Unexamined Patent Application, First Publication No. 1994-148162 (published on May 27, 1994)

It is an object of the present invention to provide an injector capable of injecting a sample gas to be analyzed in a column of a gas chromatograph in a predetermined amount.

It is another object of the present invention to provide an injection device capable of injecting a sample gas into a column of a gas chromatograph in a cost-effective manner.

In order to accomplish the above object, the apparatus for injecting a sample gas for a gas chromatograph according to the present invention is an injection apparatus for injecting a predetermined amount of a sample gas into a column provided in a gas chromatograph, A first inlet connected to the inlet, a second inlet located adjacent to the first inlet, and a second inlet located adjacent to the first inlet and the second inlet, respectively, and connected to the column through the carrier gas inlet A first three-way valve including a third inlet; A fifth inlet connected to the second inlet and a fifth inlet connected to the sample gas inflow path which is located adjacent to the fourth inlet and into which the sample gas flows and a second inlet connected to the fourth inlet and the fifth inlet, A second three-way valve including a sixth inlet located therein; A sample loop connected to the sixth inlet and filled with a sample gas through which the sample gas flows; A seventh inlet connected to the sample loop, an eighth inlet connected to the sample gas outlet path which is located adjacent to the seventh inlet and through which the sample gas flowing through the sample gas inlet path flows out, And a ninth inlet located adjacent to the eighth inlet and connected to the carrier gas inflow passage between the third inlet and the column; And a controller for controlling the opening and closing of the first three-way valve, the second three-way valve and the third three-way valve so that the sample gas filled in the sample loop is injected into the column.

At this time, when the sample gas metering device is in the preparation mode, the control unit closes the second inlet of the first three-way valve and opens the first inlet and the third inlet to open the carrier gas inflow path The fourth inlet of the second three-way valve is closed, the fifth inlet and the sixth inlet are opened, the ninth inlet of the third three-way valve is closed And the seventh inlet and the eighth inlet are opened to fill the sample loop with the sample gas.

When the sample gas metering device is in the operating mode, the control unit closes the third inlet of the first three-way valve and opens the first inlet and the second inlet, and the second three- Closing the fifth inlet and opening the fourth inlet and the sixth inlet, closing the eighth inlet of the third three-way valve and opening the seventh inlet and the ninth inlet, The sample gas filled in the sample loop is injected into the column by the carrier gas flowing through the sample loop.

According to the injection apparatus of the present invention, since the control unit controls the opening and closing of three three-way valves, the sample gas to be analyzed can be injected into the column of the gas chromatograph in a fixed amount, and the use of the comparatively cheap three- It is possible to realize the injection of the sample gas in a cost-effective manner.

1 is a schematic view showing a carrier gas storage container connected to a gas chromatograph.
FIG. 2 is a view showing a case where the sample gas metering device according to the present invention is in the preparation mode.
3 is a view showing the case where the sample gas metering device according to the present invention is in the operating mode.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a sample gas dosing device for a gas chromatograph according to the present invention will be described in detail with reference to the accompanying drawings. The detailed description of known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted.

1 is a schematic view showing a carrier gas storage container connected to a gas chromatograph.

The carrier gas storage container stores a carrier gas such as helium, hydrogen, nitrogen, and oxygen. The carrier gas flows into the gas chromatograph through the carrier gas inlet path 10.

On the other hand, the sample gas metering device 1000 provided in the gas chromatograph is connected to the sample gas inflow path 20 and the sample gas outflow path 30, respectively.

A sample gas to be analyzed is introduced into the sample gas inflow path (20) through a gas chromatograph. The sample gas introduced into the gas chromatograph fills the inside of the sample loop, and the other sample gas flows out to the outside through the sample gas outlet path (30). The sample gas filled in the sample loop is injected into the column 40 of the gas chromatograph by the carrier gas flowing through the carrier gas inflow path 10.

When the sample gas is injected into the column 40, the column 40 separates the constituents constituting the sample gas using concentration equilibrium.

Hereinafter, with reference to FIG. 2 and FIG. 3, a method of injecting the sample gas into the column 40 of the gas chromatograph in a fixed amount will be described in more detail.

FIG. 2 is a view showing a case where the sample gas metering injection device according to the present invention is in the preparation mode, and FIG. 3 is a view showing a case where the sample gas metering injection device according to the present invention is in the operation mode.

2 and 3 mean that there is a flow of gas (carrier gas, sample gas), and the dotted line indication means that there is no flow of gas (carrier gas, sample gas).

2 and 3, the sample gas metering device 1000 according to the present invention includes a first three-way valve 100, a second three-way valve 200, a sample loop 300, and a third three- 400, and may include a controller (not shown) for controlling the opening and closing of three three-way valves 100, 200, and 400.

The first three-way valve 100 includes a first inlet 110 connected to the carrier gas inflow passage 10 into which the carrier gas flows, a second inlet 120 positioned adjacent to the first inlet 110, And a third inlet 130 positioned adjacent to the first inlet 110 and the second inlet 120 and connected to the column 40 through the carrier gas inlet 10.

The first inlet 110 is an inlet through which the carrier gas flows directly through the carrier gas inflow path 10 and the second inlet 120 is connected to the fourth inlet 210 of the second three- So that the carrier gas flows into the second three-way valve 200. The third inlet 130 allows the carrier gas introduced into the first inlet 110 to be supplied to the column 40 through the carrier gas inlet passage 10 connected to the column 40.

The second three-way valve 200 includes a fourth inlet 210 connected to the second inlet 120 of the first three-way valve 100 and a second inlet 210 located adjacent to the fourth inlet 210, A fifth inlet 220 connected to the gas inlet 20 and a sixth inlet 230 positioned adjacent to the fourth inlet 210 and the fifth inlet 220, respectively.

The fourth inlet 210 is provided with a carrier gas from the second inlet 120 and the fifth inlet 220 is an inlet through which the sample gas directly flows into the sample gas inlet 20. The sixth inlet 230 receives a carrier gas from the fourth inlet 210 to introduce the carrier gas into a sample loop 300 to be described later or receives a sample gas from the fifth inlet 220 And serves to introduce the sample gas into a sample loop 300 to be described later.

The sample loop 300 is connected to the sixth inlet 230 of the second three-way valve 200 and the interior of the sample loop 300 is connected to the sample gas inlet 20, the fifth inlet 220, And may be filled with the sample gas flowing through the inlet 230. The sample gas filled in the sample loop 300 passes through the carrier gas inflow path 10, the first inlet 110, the second inlet 120, the fourth inlet 210 and the sixth inlet 230 And is then injected into the column 40 through the seventh inlet 410 and the ninth inlet 430, which will be described later.

The third three-way valve 400 includes a seventh inlet 410 connected to the sample loop 300 and a second inlet 410 located adjacent to the seventh inlet 410 and connected to the sample gas inlet passage 20, An eighth inlet 420 connected to the sample gas outflow path 30 through which the third inlet 130 and the column outlet 30 are connected to each other and a second inlet 420 located adjacent to the seventh inlet 410 and the eighth inlet 420, And a ninth inlet (430) connected to the carrier gas inflow path (10) between the inlet (40).

The seventh inlet 410 receives the sample gas flowing along the channel formed by the sample gas inlet 20, the fifth inlet 220, the sixth inlet 230 and the sample loop 300, So that the sample gas can be discharged through the eighth inlet (420) and the sample gas outflow path (30). In this process, the sample loop 300 is filled with sample gas in an amount proportional to the length of the sample loop 300, and then the sample gas filled in the sample loop 300 is controlled by a control unit To be injected into the column 40 through the seventh inlet 410 and the ninth inlet 430.

The control unit (not shown) includes a first three-way valve 100, a second three-way valve 200, and a third three-way valve 400 so that the sample gas filled in the sample loop 300 can be injected into the column 40. [ And the like. For example, the control unit transmits a control signal to the electromagnets provided in each of the three-way valves 100, 200, and 400 so that the electromagnet opens a part of the inlets of the three- Opening and closing can be controlled.

Hereinafter, the control unit controls the opening and closing of the three-way valves 100, 200, and 400 so that the sample gas flowing through the sample gas inflow path 20 is filled in the sample loop 300, A case where the sample gas filled in the sample loop 300 is pushed by the carrier gas introduced through the carrier gas inflow path 10 and injected into the column 40 of the gas chromatograph will be described.

2 is a flow chart showing the operation of the control unit for controlling opening and closing of the three-way valves 100, 200 and 400 when the sample gas metering device 1000 is in the preparation mode, And the sample gas is filled in the sample loop 300. FIG.

Specifically, when the sample gas metering device 1000 is in the preparation mode, the control unit closes the second inlet 120 of the first three-way valve 100 and opens the first inlet 110 and the third inlet 130 Is opened to allow the carrier gas flowing through the carrier gas inflow path 10 to be supplied to the column 40 of the gas chromatograph.

The control unit closes the fourth inlet 210 of the second three-way valve 200 and opens the fifth inlet 220 and the sixth inlet 230, and the ninth inlet of the third three- The third inlet 430 and the seventh inlet 410 and the eighth inlet 420 are opened to allow the sample gas flowing through the sample gas inlet path 20 to be filled in the sample loop 300.

That is, in this case, the sample loop 300 is filled with sample gas in an amount proportional to the length in which the sample loop 300 is formed, and the other sample gases are introduced into the seventh inlet 410, the eighth inlet 410 And the sample gas outflow path 30, as shown in FIG.

FIG. 3 is a schematic view showing a case where the sample gas metering device 1000 is in the operating mode as the control unit controls the opening and closing of the respective three-way valves 100, 200 and 400, Is injected into the column (40).

Specifically, when the sample gas metering device 1000 is in the operating mode, the controller closes the third inlet 130 of the first three-way valve 100 and opens the first inlet 110 and the second inlet 120 The fifth inlet 220 of the second three-way valve 200 is closed and the fourth inlet 210 and the sixth inlet 230 are opened and the eighth inlet of the third three- The sample inlet 400 is closed and the seventh inlet 410 and the ninth inlet 430 are opened so that the sample gas 300 filled in the sample loop 300 by the carrier gas flowing through the carrier gas inlet path 10 Is injected into the column 40 of the gas chromatograph.

That is, in this case, since a predetermined amount of the sample gas filled in the sample loop 300 is directly introduced into the column 40 of the gas chromatograph in the column 40 of the gas chromatograph, The precision of the gas injection amount can be greatly improved and the injection of the sample gas can be realized economically by using the three-way valve which is relatively inexpensive.

10: Carrier gas inflow path 20: Sample gas inflow path
30: Sample gas outlet line 40: Column
100: first three-way valve 110: first inlet
120: Second entrance 130: Third entrance
200: second three-way valve 210: fourth inlet
220: fifth inlet 230: sixth inlet
300: Sample loop
400: third three-way valve 410: seventh inlet
420: eighth inlet 430: ninth inlet
1000: Sample gas dosing device

Claims (3)

An injection device provided in a gas chromatograph for injecting a predetermined amount of a sample gas into a column,
A first inlet connected to a carrier gas inflow path through which a carrier gas flows, a second inlet positioned adjacent to the first inlet, and a second inlet positioned adjacent to the first inlet and the second inlet, A first three-way valve including a third inlet connected to the column via a second three-way valve;
A fifth inlet connected to the second inlet and a fifth inlet connected to the sample gas inflow path which is located adjacent to the fourth inlet and into which the sample gas flows and a second inlet connected to the fourth inlet and the fifth inlet, A second three-way valve including a sixth inlet located therein;
A sample loop connected to the sixth inlet and filled with a sample gas through which the sample gas flows;
A seventh inlet connected to the sample loop, an eighth inlet connected to the sample gas outlet path which is located adjacent to the seventh inlet and through which the sample gas flowing through the sample gas inlet path flows out, And a ninth inlet located adjacent to the eighth inlet and connected to the carrier gas inflow passage between the third inlet and the column; And
And a controller for controlling the opening and closing of the first three-way valve, the second three-way valve and the third three-way valve so that the sample gas filled in the sample loop is injected into the column.
The method according to claim 1,
When the sample gas metering device is in the preparation mode,
Closing the second inlet of the first three-way valve and opening the first inlet and the third inlet so that the carrier gas flowing through the carrier gas inflow path is supplied to the column,
Closing the fourth inlet of the second three-way valve and opening the fifth inlet and the sixth inlet, closing the ninth inlet of the third three-way valve and opening the seventh inlet and the eighth inlet, And the sample gas is filled in the sample loop.
3. The method of claim 2,
When the sample gas metering device is in the operating mode,
Closing the third inlet of the first three-way valve and opening the first inlet and the second inlet, closing the fifth inlet of the second three-way valve and opening the fourth inlet and the sixth inlet, The eighth inlet of the third three-way valve is closed and the seventh inlet and the ninth inlet are opened so that the sample gas filled in the sample loop by the carrier gas flowing through the carrier gas inflow passage flows into the column, So as to be injected into the gas chromatograph.

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