JPH0819724A - Carbon dioxide separation-collection apparatus - Google Patents

Abstract

PURPOSE:To provide a carbon dioxide separation-collection apparatus which can recover carbon dioxide in exhalation efficiently in a short time and at low costs. CONSTITUTION:After the pressure of a system being reduced by a vacuum pump 18, an exhalation specimen is introduced into a gas separation chamber 30 from a collection bag 10 through a valve 12, and carbon dioxide passes selectively through a gas separation membrane 16 to be frozen in a cold trap 32. In this process, a pressure difference, which is generated constantly between the primary side and the secondary side of the gas separation membrane 16, is driving power to separate carbon dioxide continuously from the exhalation specimen.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a carbon dioxide gas separation and collection device,
In particular, it relates to a carbon dioxide gas separation / collection device used for analysis of carbon dioxide gas contained in exhaled breath.

[0002]

2. Description of the Related Art In modern medicine, clinical biochemical tests are indispensable for diagnosis of diseases.
Blood, urine, and the like are typical samples for this clinical biochemical test. However, it has recently been proposed to use exhaled breath as a specimen for this clinical biochemistry test. Exhaled air is constantly released by living humans, so it is easy to collect it, and a small amount of volatile components in mixed venous blood flowing through alveolar capillaries are contained in the exhaled gas by gas exchange. Therefore, it is considered that it is possible to make a diagnosis of a disease by utilizing the exhaled breath.

For example, Helicobacter pylori (hereinafter referred to as H. pylori), which has recently been attracting attention as a cause of gastric ulcer, produces an enzyme that decomposes urea and produces ammonia in order to live in the strong acidity of the stomach. It creates and keeps its surroundings alkaline to protect itself from the strong acidity of stomach acid. When urea is decomposed, carbon dioxide gas is generated, and this carbon dioxide gas is absorbed from the blood vessels of the stomach and is carried to the lungs so that it is included in the exhaled gas by the above-mentioned gas exchange. Therefore, the patient drink labeled urea, for example C ^13, it is possible to know whether H. pylori in the stomach by analyzing the carbon dioxide gas containing C ¹³ present in the exhaled breath is present.

[0004] Generally, as a method for collecting carbon dioxide gas, an adsorption (absorption) method, a membrane separation method, a cryogenic separation method and the like have been conventionally performed. The adsorption (absorption) method is a method of using a solid or liquid adsorbent (absorption material) to adsorb (absorb) carbon dioxide gas, and then recover the carbon dioxide gas by heat treatment or the like.

The membrane separation method is a method of separating carbon dioxide gas from a sample gas by using a gas separation membrane which selectively permeates carbon dioxide gas contained in the sample gas.

The cryogenic separation method focuses on the property that carbon dioxide liquefies or solidifies at a relatively high temperature, and cools the sample gas to a temperature close to the boiling point or freezing point of carbon dioxide,
It is a method of liquefying or solidifying carbon dioxide to recover it.

FIG. 2 shows an apparatus for carrying out the conventional membrane separation method. In FIG. 2, the sample gas is introduced into the gas separation chamber 14 through the valve 12 from the sample gas collection bag 10 such as a tetra bag.
A gas separation membrane 16 is provided in the gas separation chamber 14, and carbon dioxide gas in the sample gas is selectively permeated through the gas separation membrane 16 for separation. This carbon dioxide gas separation operation is performed by the gas separation membrane 16 of the gas separation chamber 14.
It is carried out while pulling a vacuum on the secondary side of the vacuum pump 18. The carbon dioxide gas sucked by the vacuum pump 18 is collected by the sample cell 20 provided on the discharge side of the vacuum pump 18. In addition, in order to increase the differential pressure between the primary side and the secondary side of the gas separation membrane 16 and increase the recovery rate of carbon dioxide gas, it is possible to perform the separation operation while pressurizing the primary side.

FIG. 3 shows an apparatus for carrying out the conventional cryogenic separation method. The sample gas in the collection bag 10 is introduced into the cryogenic separation chamber 22 via the valve 12. The cryogenic separation chamber 22 is provided with a sample tube 24 for passing a sample gas, a cooler 26 for cooling the sample tube, and a heater 28 for heating the sample tube 24. Before performing the operation of separating carbon dioxide gas, the sample tube 24 is evacuated by the vacuum pump 18.

When the sample gas containing carbon dioxide gas is introduced from the collection bag 10 into the sample tube 24 which is evacuated, the sample gas is cooled by the cooler 26 and the carbon dioxide gas and impurities having a high boiling point are liquefied or Solidify. Next, when the sample tube 24 is heated by the heater 28, the liquefied or solidified carbon dioxide gas becomes a gas and the sample cell 20
To be collected by. At this time, the liquefied or solidified impurities in the sample tube 24 can be separated from the carbon dioxide gas by controlling the heating temperature.

[0010]

However, the above-mentioned conventional method has the following problems.

In the adsorption (absorption) method, it takes a long time to recover carbon dioxide, and the absorption efficiency and the recovery efficiency cannot be increased so much, and it is very difficult to keep the respective efficiencies constant. Therefore, there is a problem that it is not suitable for collecting carbon dioxide gas as it is.

In the membrane separation method, the power for passing the carbon dioxide gas through the gas separation membrane 16 is required, and as described above, the secondary side of the gas separation membrane is constantly evacuated by the vacuum pump 18. However, the concentration of carbon dioxide in the exhaled breath is about 3%
Since it is low, it is necessary to pressurize the primary side of the gas separation membrane 16 in order to further increase the recovery rate, and there is a problem that equipment and cost for depressurizing and pressurizing these are required. Further, the pressure applied to the primary side is also limited in terms of pressure resistance of the gas separation membrane 16, and there is a problem that the recovery rate cannot be increased so much. Furthermore, this method has a problem that the amount of carbon dioxide gas leaked from the vacuum pump 18 cannot be ignored.

In the cryogenic separation method, since the concentration of carbon dioxide gas in the exhaled breath is low as described above, the internal pressure of the sample tube 24 cannot be lowered so much even if only the carbon dioxide gas is liquefied or solidified. As a result, there is a problem that the movement of the sample gas from the collection bag 10 to the sample tube 24 is stopped during the collection, and the recovery rate of the carbon dioxide gas cannot be increased. On the other hand, in order to increase the recovery rate of carbon dioxide gas, it is necessary to simultaneously liquefy the components gas in the air such as nitrogen and oxygen. For this reason, it is necessary to lower the cooling temperature to the liquid nitrogen temperature, and there is also a problem that the cost for that is increased. Furthermore, since the impurity gas liquefied or solidified together with carbon dioxide needs to be finally separated from carbon dioxide, there is also a problem that the temperature control for the boiling point of each gas is complicated during heating and recovery of carbon dioxide by the heater 28. there were.

The present invention has been made in view of the above conventional problems, and an object of the present invention is to provide a carbon dioxide gas separation / collection device which can recover carbon dioxide gas in exhaled air with high efficiency in a short time and at low cost. is there.

[0015]

In order to achieve the above object, the present invention is a carbon dioxide gas separation and collection apparatus for separating and collecting carbon dioxide gas contained in exhaled breath, which comprises: A gas separation chamber in which separation is performed, a breath sample introduction means for introducing a breath sample into the chamber, and a gas which is provided in the chamber and selectively permeates carbon dioxide gas in the introduced breath sample. A separation membrane,
A cooling unit which is provided in the chamber on the downstream side of the gas separation membrane and cools the carbon dioxide gas separated by the gas separation membrane.

[0016]

According to the above construction, the carbon dioxide gas in the sample gas is separated by the gas separation membrane, and the separated carbon dioxide gas is condensed by the cooling means so that the volume thereof is reduced and the gas separation membrane of the gas separation chamber is formed. Since the partial pressure of carbon dioxide on the secondary side is always kept lower than the partial pressure on the primary side, it is not necessary to externally apply power for passing carbon dioxide through the gas separation membrane.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram of a carbon dioxide gas separation / collection device according to the present invention. The same members as those in the conventional example shown in FIGS. 2 and 3 are designated by the same reference numerals and their description is omitted. .

In FIG. 1, a gas separation chamber 30 is provided in a gas separation chamber 30 for selectively permeating carbon dioxide gas in exhaled gas and for cooling and freezing carbon dioxide gas which has permeated the gas separation membrane 16. A cold trap 32 as a cooling means is provided.

As a material of the above-mentioned gas separation membrane 16, for example, cellulose acetate, polyimide or polysulfone is used.

Further, the apparatus shown in FIG. 1 is provided with a valve 12 for introducing an exhaled sample from the collection bag 10 into the gas separation chamber 30 and a vacuum pump 18 for drawing a vacuum in the system. There is. Here, the valve 12 constitutes the exhaled breath sample introduction means of the present invention.

Next, the operation of the apparatus of this embodiment will be described.

In the apparatus of the present embodiment, the gas separation chamber 3 is set by the vacuum pump 18 before the carbon dioxide separation operation.
Depressurize to zero. This pressure reducing operation is performed by closing the valve 12 and opening the valves 34 and 36. Next, the valves 34 and 36 are closed, the valve 12 is opened, and the exhaled breath sample is introduced into the gas separation chamber 30 from the collection bag 10. When the breath sample is introduced into the gas separation chamber 30, only carbon dioxide gas therein passes through the gas separation membrane 16 and is separated. This carbon dioxide gas is cooled and solidified by the cold trap 32.

The carbon dioxide gas separated by the gas separation membrane 16 is solidified by the cold trap 32,
On the secondary side of the gas separation membrane 16, the partial pressure of carbon dioxide gas is always kept at the solid-gas equilibrium pressure. On the other hand, the pressure on the primary side of the gas separation membrane 16 is the pressure of the collection bag 10, which is usually 1 atm (atmospheric pressure), so that there is always a pressure difference between the primary side and the secondary side of the gas separation membrane 16. Will be. This pressure difference becomes drive power, and carbon dioxide gas passes from the primary side of the gas separation membrane 16 toward the secondary side.

Therefore, it is not necessary to constantly pull the secondary side of the gas separation membrane with a vacuum pump, and low-cost operation is possible. Further, since the carbon dioxide gas continues to be separated while the carbon dioxide gas is solidified in the cold trap 32, the carbon dioxide pressures on the primary side and the secondary side do not reach equilibrium, and the recovery rate can be increased. . Further, in the apparatus of the present embodiment, only carbon dioxide gas is cooled and solidified, and no other impurities are contained, so that complicated temperature control is not required at the time of carbon dioxide gas recovery.

Particularly, exhaled breath contains a large amount of water vapor, but by using a membrane that does not permeate the water vapor, the water vapor can be easily separated, and the separation of water vapor does not take time. It is very suitable for diagnosis of.

As described above, in the cold trap 32 of the apparatus of this embodiment, only the carbon dioxide gas needs to be frozen, so the temperature may be about -80 degrees (193k) and up to the liquid nitrogen temperature (77k). There is no need to create a low temperature.
From this point as well, the cost can be reduced.

The carbon dioxide gas frozen in the cold trap 32 can be collected in the sample cell 20 through the valve 34 by performing appropriate heating. Further, if the cold trap 32 is formed of a porous metal material or the like, and its volume is reduced while keeping its surface area large,
This is convenient when carrying the cold trap 32 together with the carbon dioxide gas being frozen. Cold trap 32
In addition to the above-mentioned porous material, a shape having fins may be used.

[0029]

As described above, according to the present invention,
The carbon dioxide gas in the sample gas is separated by the gas separation membrane, and the separated carbon dioxide gas is condensed by the cooling means so that the volume of the carbon dioxide gas is reduced and the amount of the carbon dioxide gas on the secondary side of the gas separation membrane in the gas separation chamber is reduced. Since the pressure is always kept lower than the partial pressure on the primary side, it is not necessary to externally apply power for passing carbon dioxide through the gas separation membrane. Further, the cooling temperature of the cooling means may be a temperature at which carbon dioxide gas freezes, and it is not necessary to lower it to the liquid nitrogen temperature. Therefore, a low-cost device can be supplied.

Further, as long as the freezing of the carbon dioxide gas by the cold trap continues, the carbon dioxide gas is separated, so that the recovery rate can be increased.

Further, since it takes no time to recover carbon dioxide,
It is also effective in increasing the operating rate in clinical tests such as breath analysis.

As described above, it is possible to provide a carbon dioxide gas separation / collection device which can recover carbon dioxide gas in exhaled air with high efficiency in a short time at low cost.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an embodiment of a carbon dioxide gas separation / collection device according to the present invention.

FIG. 2 is a configuration diagram of an apparatus for performing a conventional membrane separation method.

FIG. 3 is a configuration diagram of an apparatus for performing a conventional cryogenic separation method.

[Explanation of symbols]

 10 Collection Bag 12, 34, 36 Valve 16 Gas Separation Membrane 18 Vacuum Pump 20 Sample Cell 30 Gas Separation Chamber 32 Cold Trap

Claims (1)

[Claims] 1. A carbon dioxide gas separation and collection device for separating and collecting carbon dioxide gas contained in exhaled breath, comprising a gas separation chamber for separating carbon dioxide gas, and a breath sample in the chamber. Exhaled breath sample introduction means for introducing, a gas separation membrane provided in the chamber, which selectively permeates carbon dioxide gas in the introduced exhaled breath sample, and in the chamber on the downstream side of the gas separation membrane. A carbon dioxide gas separation / collection device comprising: a cooling unit which is provided and cools the carbon dioxide gas separated by the gas separation membrane.