JP2912105B2 - Gas sampling method and apparatus for multiple systems - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas sampling method and a gas sampling system for sampling a plurality of gas lines sequentially from a plurality of gas lines for quantitative analysis.

[0002]

2. Description of the Related Art The analysis technique of gas chromatography (hereinafter abbreviated as GC) is a column chromatography method using a carrier gas as a mobile phase and a liquid or solid as a stationary phase. It is used for quantification and is used in various fields.

[0003] A basic GC apparatus includes a column installed in a constant temperature chamber maintained at a predetermined temperature, and a sample to be examined on the way of a carrier gas introduced into the column via a flow control device. Between the sample introduction part or injection part that mixes the liquid and the liquid or solid stationary phase packed or coated in the column (adsorption, solubility, chemical bonding)
A detector for detecting the concentration peak of each component separated in the column by the difference between the two, and a recorder for recording the detection result.

[0004] G used for actual gas analysis and R & D
As the C device, the above-mentioned basic GC device, for example, a device which is automatically controlled in combination with a computer so as to automatically perform, for example, temperature control of a constant temperature chamber, flow rate control, sample introduction, or component detection, etc. Is being developed.

[0005]

In the fields of development of various gas generating agents, gas absorbents, adsorbents, etc., analysis and development of batteries, and analysis of catalytic reactions, a plurality of gas systems having different conditions are used. You may want to perform analysis in parallel. In recent years, it is important to investigate the physiology of fruits and vegetables in fields such as new technologies for maintaining freshness of fruits and vegetables, and for that purpose, it is necessary to measure the gas and respiratory volume generated by fruits and vegetables under various gas composition environments. Occurs.

However, even in such a case, if an attempt is made to analyze and measure using the above-described conventional GC apparatus, the conventional GC sampling apparatus can perform only one system of gas analysis. Can not do it. Therefore, in such a case, the next condition is set after the analysis and measurement are completed under one condition,
It is necessary to carry out the next analysis and measurement and repeat this endlessly, and the operation becomes extremely long and the efficiency becomes poor.

In order to perform parallel work, it is necessary to provide the GC devices in parallel to perform analysis and measurement, which increases the equipment cost and obtains the analysis results separately. There are problems such as complicated processing.

The present invention takes into account the problem of the method of collecting gas when analyzing a plurality of system gases by the above-mentioned conventional GC apparatus, and selects any one of a plurality of lines of different composition gas to thereby analyze the gas. An object of the present invention is to provide a gas sampling method and apparatus of a plurality of systems that can measure a mixed gas and efficiently send the gas to a GC apparatus and are suitable for automation.

[0009]

According to the present invention, as a means for solving the above problems, a plurality of types of mixed gas to be analyzed are used.
Each of the mixed gas Shi out feed from the storage chamber in parallel
Circulating La <br/> in that the one of the mixed gas, the circulating feed and exhaust the residual gas by selecting one of the the return analysis gas line of a plurality system to return to the storage chamber via a line back is to feed, circulation la containing the analysis gas line gas mixture during passage of the circulating line to the connected metering line
And the line pressure of the metering line are equilibrated, the gas in the metering line is cut off from the circulation line, and the pressure is equilibrated with a predetermined external pressure for a few seconds, and then the gas volume is measured. The gas sampling method of a plurality of systems consisting of feeding into a column of a gas chromatograph in addition to the line was adopted.

As another means for solving the above problems,
Storage chambers for storing multiple specimens under different environmental conditions, and multiple types of mixed gas to be analyzed from these chambers
Mixed gas of each Shi out sending class in parallel are sent back
Switching valve and, switching in which a mixed gas is fed through the valve to the intermediate path of the circulation line for circulating pumps for selecting one of a plurality of analysis gas line that is returned to the storage chamber via a return line A valve, a gas metering pipe provided in a gas metering line connected through the valve, a pressure equilibrium valve provided in a circulation line path for equilibrating a gas to be measured with a predetermined external pressure, The configuration of a gas sampling device of a plurality of systems including an exhaust valve for exhausting gas remaining in the circulation line in the path is adopted.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. The analyzer of the embodiment is an example used to develop a freshness preserving technique of what kind of environmental conditions can preserve freshness of fruits and vegetables, for example, apples and oranges, in order to preserve freshness of these fruits and vegetables. Although shown, it will be obvious to those skilled in the art that the present invention can be applied to various other applications under similar conditions.

FIG. 1 is an overall schematic system diagram of a gas analyzer according to an embodiment. This gas analyzer comprises a plurality of gas sampling units A and a gas chromatograph (hereinafter abbreviated as GC) device unit B. The GC device unit B has two types of G units.
Although the C apparatus is shown, only one of them may be used to carry out the analysis method of the present invention.

A plurality of gas sampling units A pass through a constant temperature chamber 2 in which the mixed gas of the cylinder 1 is fed and the specimen X is stored, and a gas system line 3 which sends the mixed gas generated in the constant temperature chamber in parallel. The intake side switching valve 4 for selecting and switching one of the lines, a circulation line 6 connected to the switching valve 4, a circulation pump 7 and a circulation line 6 connected to the circulation line 6, A return side switching valve 5 for switching to the gas system line 3 returning from the line 6 is provided.

As shown in the figure, a plurality of cylinders 1a to 1e (five cylinders in the embodiment) are prepared as shown in the figure, and a storage chamber 2a for independently storing the inspection objects X in the constant temperature chamber 2 is provided.
~ 2e. For the inspection object X, those having different compositions of the mixed gas of the cylinders 1a and 1e are prepared so that different environmental conditions are obtained in the respective storage rooms 2a to 2e.

For example, in the cylinder 1a, N ₂ 80%, O ₂
19%, CO ₂ 0.3%, other 0.7%, cylinder 1b
In this example, the proportions of the mixed gas components are slightly different, such as 82% for N ₂ , 17% for O ₂ , 0.1% for CO ₂ , and 0.9% for others. Although not shown, the supply of the mixed gas is performed for each of the constituent gases, and the storage chambers 2a to 2e are provided.
Before sending the mixed gas to the storage chamber, a mixing device may be provided to create a mixed gas having a desired mixing ratio, and the mixed gas may be sent to each storage chamber.

In this embodiment, a rotary cock is used as the switching valve 5 for selecting and connecting any one of the paths of the gas system lines 3 provided in parallel. Are used in conjunction with each other. The switching valve 5 may be of any type other than the rotary cock type as long as it has an equivalent switching function.

A circulation pump 7 provided in the circulation line 6
Is not limited to the illustrated position, and may be provided further downstream, and the installation position is arbitrary. Reference numerals 6a, 6b, and 6c in the circulation line 6 denote three-way cocks, each having a flow path that is directly inserted into the circulation line and a flow path that communicates with the outside air. The channel 6x leading to the outside air is formed by a thin Teflon tube. Each three-way cock 6a, 6b,
When the flow path 6c is switched to the flow path leading to the outside air, the flow upstream of the cock 6a, downstream of the cock 6b, and downstream of the cock 6c is interrupted at each of the cocks, downstream of the cock 6a, upstream of the cock 6b, and upstream of the cock 6c. Is opened to a predetermined external pressure. The three-way cocks 6a, 6b, and 6c may have the same function as the above using two two-way cocks.

In the course of the circulation line 6, other switching valves 8 and 12 are provided as shown in the figure, whereby the mixed gas in the circulation line 6 is sent to the respective GC devices. Measuring pipes 9 and 13 for measuring the flow rate of the mixed gas are connected to the switching valves 8 and 12, respectively. Switching valve 8, 1
The type 2 is also used in this embodiment as a channel switching type, and it goes without saying that another type may be used as long as it has the same function.

The flow paths of the mixed gas measured by the measuring pipes 9 and 13 are switched by switching valves 8 and 12, and gas cylinders 10 and 14 filled with a carrier gas of an inert gas.
And are connected to the carrier gas lines via switching valves 8 and 12 and sent to the respective GC devices 11 and 15.

FIG. 2 is an enlarged view of the vicinity of the GC devices 11 and 15. Each of the GC devices 11 and 15 is a general GC
The GC devices 11 and 15 are the same as the devices, and the switching devices 8 and
The mixed gas sent from 12 is separated through columns 16 and 18, and each component is detected by detectors 17 and 19. In this case, the detector 17 of the preceding GC device 11 is composed of a thermal conductivity type detector (generally abbreviated as TCD),
It is suitable for detecting inorganic gas components such as CO ₂ , O ₂ , N _{2 and the} like.

On the other hand, the detector 19 of the GC device 15 at the subsequent stage
Consists of a flame ionization detector (generally abbreviated as FID) and comprises an organic gaseous component such as ethylene C ₂ H
_4. Suitable for detecting acetaldehyde CH ₃ CHO, ethyl alcohol C ₂ H ₅ OH, etc. In addition, other types of detectors include an electron capture type detector (EC
D), a frame luminous intensity detector (FPD), and the like. The data detected by the detectors 17 and 19 are sent to a computer 20 where they are recorded and analyzed.

In the gas analyzer of the embodiment configured as described above, the sampling method of the present invention is implemented as follows. Although the procedure of the gas sampling method of the present invention is not necessarily in the order described below, the operation of feeding gas from the cylinder 1 in FIG. 1 will be described for easy understanding.

Storage chambers 2a, 2b in constant temperature chamber 2 in FIG.
Fruits and fruits, for example, fruit X, under the same conditions are stored in 2e, and a cylinder 1a is stored in each of the storage rooms 2a to 2e.
~ 1e, mixed gas of different composition is sent and is kept under the environment of various conditions. Then, the mixed gas containing the gas generated from the fruit X in each storage room is sent to the intake side switching valve 4 through each gas system line 3.

When the intake side switching valve 4 and the return side switching valve 5 are rotated to select one of the gas lines, the selected gas line is connected to the circulation line 6. In the state of FIG. 1, the three-way cocks 6a, 6a
For b and 6c, it is assumed that cocks are set so that all the circulation lines communicate. It is also assumed that the switching valves 8 and 12 are initially set to the phase in which the ports 5 and 6 respectively communicate. Next, the circulating pump 7 is started, and the three-way cock 6c provided in the circulating line 6 is operated so as to communicate with the outside air and shut off the downstream part, thereby exhausting the gas analyzed last time for a certain time.

Next, the three-way cock 6c is operated to close the flow path 6x to the outside air, and is connected to the circulation line. The pump is operated for a certain time to circulate the mixed gas to the circulation line 6. In this case, the gas circulated in the circulation line 6 is returned to the storage chambers 2a to 2e through the return line of the selected one of the gas lines 3. This is storage room 2
This is because the gas generated in a to 2e is extracted as much as possible without changing the gas atmosphere in the storage chamber. In the method without the return line, the flow rate of the mixed gas in the storage chamber increases, or the storage chamber enters a negative pressure state, and the composition of the gas changes. However, the above method can suppress this.

When the mixed gas circulates sufficiently in the circulation line, the pump is stopped, and the pressure in the measuring pipe and the pressure in one of the selected gas system lines 3 to be analyzed are equilibrated so that the same gas as in the storage chamber is filled in the measuring pipe. take in. This pressure equilibrium is often an operation that is necessary every time a gas system is selected and analyzed, in which the pressure of the mixed gas from the cylinder 1 sent into each of the storage chambers 2a to 2e is slightly different.

When the pressures are balanced, the three-way cocks 6a, 6b
Is operated to change the line including the measuring pipes 9 and 13 into the circulation line 6.
From the line upstream of the three-way cock 6a and the line downstream of the three-way cock 6b, open both ends of the line including the measuring pipes 9 and 13 to the outside air, and measure the pressure equilibrium between the outside air of a predetermined pressure and the gas pressure of the measuring pipe section. Close for 2 seconds and close the cock.

Thereafter, the switching valves 8 and 12 are operated so that the ports 5 and 6 of the switching valves 8 and 12 are switched so as to overlap the ports 2 and 1, and the gas in the measuring pipe section is connected to the carrier gas line, and the GC device is operated. Send it to either 11 or 15. In the above-described apparatus, the gas in the measuring tube is supplied to the GC devices 11 and 15 by performing either one of the GC devices 11 and 15 first and then performing the other, or by simultaneously performing the two in parallel. Is also good.

When the above operation is completed, the switching valve 5 is switched to another one of the gas lines 3 to take in a new gas, and the above procedure is repeated. It is convenient if the switching valve 4 for taking in the measuring gas line from the measuring gas line and the switching valve 5 for returning the measuring gas line to the measuring gas line are linked.

The above operation may be performed based on signals from one or more GC devices. When the signal from the GC device is taken into the computer 20 and the GC device is operated according to the program, the analysis value of the gas by GC is taken into the computer 20 and edited, and the analysis value over time for each gas line is graphically displayed. It is convenient. When the gas metering tube is located at room temperature, comparison with a manual analysis value using a microcylinder can be easily performed. Further, based on the detection of a power outage and the detection of the extinction of the hydrogen flame by the gas chromatograph hydrogen flame detector, a device for closing the valve of the hydrogen gas supply line and stopping one or more GCs is provided at night. It is needless to say that driving can be done safely.

[0031]

As described in detail above, in the gas sampling method of the present invention, any one of a plurality of gas lines to be analyzed is selected by the switching valve, the selected line is connected to the circulation line, and the gas is measured by the measuring pipe. Since these are sent to each GC device, these procedures can be successively and efficiently processed by operating the switching valve for each type of analysis gas, thereby automating the entire device. Above, processing can be performed very efficiently.

In addition, the gas sampling apparatus for implementing this method has the advantage that it can be implemented with a minimum of equipment for implementing the above-mentioned sampling method, and that an extremely efficient and economical apparatus can be obtained.

[Brief description of the drawings]

FIG. 1 is an overall schematic block diagram of a gas analyzer according to an embodiment.

FIG. 2 is an enlarged view of a portion of the GC device according to the embodiment.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 gas cylinder 2 constant temperature chamber 3 gas system line 4 intake side switching valve 5 return side switching valve 6 circulation line 7 circulation pump 8,12 switching valve 9,13 measuring pipe 10,14 gas cylinder 11,15 GC unit 16,18 column 17, 19 Detector 20 Computer

Continuing from the front page (72) Inventor Naoichi Sakota 4-1-1186 Okai, Fukushima-ku, Osaka-shi Inside Rengo Co., Ltd. (72) Inventor Takatoshi Kogakumaru 4-1-1186 Okai, Fukushima-ku, Osaka-shi Inside Rengo Co., Ltd. (72) Inventor ▲ Sako ▼ Kazuhiro Tada 4-1-1, Okai, Fukushima-ku, Osaka-shi Inside Rengo Co., Ltd. (72) Inventor Takeo Shiozaki 4--5 Nagata, Joto-ku, Osaka-shi No. 14 (72) Inventor Minoru Takigawa 25-19 Kamikashita, Nagaokakyo-shi (72) Inventor Keishi Inoue 2- 14-14, Jonancho, Takatsuki-shi (56) References JP-A-4-95752 (JP, A JP-A-60-89749 (JP, A) JP-A-54-27497 (JP, A) JP-A-1-110805 (JP, U) JP-A-56-148654 (JP, U) Field (Int.Cl. ⁶ , DB name) G01N 1/00 B01D 19/00 G01N 30/00

Claims (2)

(57) [Claims] 1. A storage room for storing a plurality of types of mixed gases to be analyzed.
Each feed out Shi feed gas mixture respectively in parallel from
Any of the returned and returning analysis gas line of a plurality system to return to the storage chamber via a line by selecting the one of the mixed gas, feeding to the circulation line for circulating the feed was exhausted residual gas, the circulation line a path way to the mixed gas into the attached metering line and a circulation line including the analysis gas line
The metering line is sent in such a way that the line pressure is balanced, the gas in the metering line is cut off from the circulation line, the pressure is equilibrated with a predetermined external pressure for a few seconds, the gas volume is measured, and then the carrier gas line of the gas chromatograph is used. In addition, a multi-system gas sampling method comprising feeding the gas into a column of a gas chromatograph. 2. A storage room for storing a plurality of test objects under different environmental conditions, and a mixture to be analyzed from these rooms.
Each of the mixed gas Shi out feeding a plurality of types of case gas in parallel
A switching valve for selecting one of a plurality of analysis gas line that is returned to the storage chamber via the return line and is sent back,
A switching valve provided in the middle of a circulation line for circulating a mixed gas sent through this valve by a pump, a gas metering pipe provided in a gas metering line connected via this valve, and a gas metering device. Gas sampling system comprising: a pressure equilibrium valve provided in a circulation line path for equilibrating with the outside atmospheric pressure of the air; and an exhaust valve for exhausting gas remaining in the circulation line in the circulation line path. apparatus.