JP2754161B2 - Gas flux measuring method and apparatus - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for continuously measuring gas flux over a long period of time.

[0002]

2. Description of the Related Art In recent years, with an emphasis on protecting the global environment and effectively using resources, research and monitoring of the amount of carbon dioxide gas and methane gas released from soil, water surface, and the like have been conducted around the world. Is being done. In addition, when investigating a biological system, the amount of gas released from a plant leaf or the like and the amount of gas absorbed therein are measured.

[0003] Conventional gas flux measurement methods are roughly classified into (i) a chamber method based on a material balance and (i)
i) There are micrometeorological methods based on mass transport.

In the above-described chamber method, a cylindrical or box-shaped chamber (container) is joined to a gas exchange surface, a gas is introduced into the cavity, and a gas flux (gas exchange rate) is determined based on a change in gas concentration in the chamber. ). Since this method is based on the material balance, the measurement of the flux itself can be performed simply and accurately in principle and in practice.

However, in the chamber method using a closed container (closed method), the gas concentration in the container increases (or decreases) over time with respect to the normal environmental concentration, so that the amount of generated gas (or gas) is increased. Absorption) itself may be affected. For example, measuring carbon dioxide released from soil poses a problem because the activity of the source microorganisms is affected. Therefore, this method cannot correctly measure the gas flux over a long period of time unless special measures such as intermittent exhaust treatment are taken.

According to the method (measurement method) in which the ambient air is guided into the container and ventilated in the chamber method among the chamber methods (ventilation method), such a problem can be avoided.

[0007] However, if the ventilation flow rate is too small, it determines the gas flux. On the other hand, if the ventilation flow rate is too large, correct measurement values cannot be obtained due to the influence of suction due to negative pressure. Therefore, it is necessary to determine an appropriate ventilation flow rate in advance, but since it depends on the size and shape of the container, it is not always easy to determine this.

[0008] Among the above micrometeorological methods, the eddy correlation method is a measurement method based on the definition of flux itself and does not disturb the gas exchange surface. The value can be determined.

However, since it is necessary to measure the fluctuation component between the wind speed and the gas concentration, a special anemometer and a gas concentration meter having a very quick response are required. Moreover, since it requires a relatively large area, it cannot be applied to gas exchange of pot plants and individual leaves.

[0010] Among the micrometeorological methods, the gradient method is to determine the diffusion resistance of the atmosphere from the vertical distribution of the wind speed and to determine the gas flux from this and the gas concentration difference between the two altitudes. However, this method requires a larger area than the above-mentioned eddy correlation method, and also needs to obtain a wind speed distribution in consideration of the influence of air temperature. Therefore, it is unavoidable that the measurement is extensive. Also, when the wind speed gradient is small, the error increases. Although there is a method of calculating the diffusion resistance from the heat balance, it is necessary to measure the net radiation amount in addition to the temperature and the humidity, so that the measurement is more extensive and complicated.

[0011]

As described above, in each of the above-described methods, it has been difficult to accurately measure the gas flux continuously over a long period of time using a simple apparatus. In recent years, against the background of the global warming problem and the like, it has become necessary to accurately measure gas flux in various parts of the world, and a method and apparatus capable of easily and accurately measuring gas flux at many points are demanded. .

The present invention has been made in view of the above-mentioned conventional problems, and an object of the present invention is to provide a gas flux measuring method and apparatus which can be easily and accurately measured without being easily affected by changes in the surrounding environment. It is in.

[0013]

In order to achieve the above-mentioned object, a gas flux measuring method according to the present invention comprises passing a gas to be measured through a diffusion medium having a known diffusion resistance and a uniform shape.
A gas flux of the gas to be measured is obtained using an inlet gas concentration and an outlet gas concentration of the diffusion medium and a diffusion resistance of the diffusion medium.

Further, a gas flux measuring apparatus according to the present invention has a gas inlet opening and a gas outlet opening, and a chamber through which a gas to be measured flows through an internal cavity, and the gas inlet opening and the gas outlet opening in the chamber. And a diffusion medium having a known diffusion resistance and a constant shape, and at least one gas installed to determine a gas concentration difference between an inlet side and an outlet side of the diffusion medium. And a density sensor.

[0015]

According to the gas flux measuring method of the present invention, the gas to be measured is passed through the diffusion medium, and in that state, the gas concentration difference between the inlet side and the outlet side is measured. Note that when the outlet gas concentration can use a general value in the atmosphere, the measurement of the outlet gas concentration can be omitted. The same applies to the case where the inlet side is open to the atmosphere, in which case the measurement of the inlet side gas concentration can be omitted. In any case, a gas concentration difference that is a difference between the inlet gas concentration and the outlet gas concentration is obtained, and the gas flux is calculated from the gas concentration difference and the diffusion resistance of the diffusion medium.

In the present invention, since the gas flux is measured using a diffusion medium having a known diffusion resistance, it is not necessary to measure the diffusion resistance of the diffusion medium sequentially, and simple measurement can be realized. In addition, the measurement of the gas flux can be performed accurately because it is hardly affected by changes in the surrounding environment.

According to the gas flux measuring device of the present invention, the chamber is installed on the gas generating surface (or the gas absorbing surface), and the gas discharged from the surface or the gas absorbed by the surface is introduced into the chamber. Is done. Since the space between the gas inlet opening and the outlet opening of the chamber is closed with the diffusion medium, the gas flowing from the inlet opening always passes through the diffusion medium and reaches the outlet opening. Here, unlike the conventional gradient method, the diffusion medium is made of a substance having a known diffusion resistance. For this reason, if the gas concentration difference between the inlet gas concentration and the outlet gas concentration is known, the gas flux can be calculated from the gas concentration difference and the diffusion resistance.

[0018]

FIG. 1 shows the principle of the present invention. In FIG. 1, (A) is a diagram showing the principle of gas flux measurement according to the present invention, and (B) is the measurement diagram shown in (A). It is the equivalent circuit diagram which replaced the system as an electric circuit.

In FIG. 1A, the gas flux measuring device 12 is, for example, a device for measuring the amount of carbon dioxide gas released from the soil placed on the soil surface 10A of the soil 10. The apparatus 12 is composed of a chamber 14 into which gas is introduced, and a diffusion medium 16 having a known diffusion resistance installed therein.

The carbon dioxide gas released from the soil surface 10A is introduced into the gas inlet opening of the chamber 14, passes through the inside of the chamber, and is discharged into the atmosphere from the gas outlet opening, while passing through the diffusion medium. Will do. That is, in the present invention, the gas flux is obtained by the calculation using the gas concentration difference which is the difference between the gas concentration on the inlet side and the gas concentration on the outlet side of the diffusion medium 16 and the diffusion resistance of the diffusion medium 16. .

The circuit of FIG. 1B is a diagram shown for reference to facilitate understanding of the present invention, and is an equivalent electric circuit of a gas flux measuring system in which flux is regarded as current. Diffusion resistance in the soil 10 corresponds to the resistor R _s, the diffusion resistance of the diffusion medium 16 is equivalent to the resistor R _c. In addition, the inlet gas concentration corresponds to the potential at point B, and the outlet gas concentration
It corresponds to the potential of the point. That is, the concentration difference between the inlet gas concentration and the outlet gas concentration corresponds to the potential difference between the points A and B shown in FIG.

In (B), the current i flowing through the circuit is given by the following equation according to Ohm's law. However,
E _B and E _A is the potential of each point B and the point A.

I = (E _B -E _A ) / R _c Similarly, the flux density F of carbon dioxide flowing in the diffusion medium is given by the following equation. However, C _B and C _A
Is the concentration of carbon dioxide at point B and point A, respectively.
R _c is the diffusion resistance value of the diffusion medium.

[0024] _{F = (C B -C A)} / R c current i flowing through the circuit, the total resistance R _all in the circuit, i.e., inversely proportional to _{R all = R s + R c} . Therefore, by adding R _c in the circuit, there is a possibility that the current i is underestimated. However, under the condition of R _s >> R _c , R _s / (R _s + R _c ) becomes substantially equal to 1, so that the effect on the current i by adding R _c in the circuit is practically ignored. obtain. That is, a measurement system similar to an ammeter that measures the current flowing in the circuit by connecting the circuits in series and performing work can be configured.

On the other hand, if the diffusion resistance R _c of the diffusion medium is determined by the same theory so as to satisfy the condition of R _s >> R _c , the magnitude can be obtained without affecting the carbon dioxide flux. Can be requested.

Further, since the carbon dioxide concentration C _B is in the point B chamber, which if flux is constant maintaining a constant concentration, are not over time monotonically increasing or decreasing,
Stable measurement is possible over a long period of time.

FIG. 2 shows a preferred embodiment of the gas flux measuring device according to the present invention, and FIG.
FIG. 2B is a cross-sectional view of the device 12.

In this figure, the chamber 14 in this embodiment is formed of a plastic material and has a hollow cylindrical shape with a hollow inside. One side (lower in the figure) is an inlet opening, and the other side (upper in the figure).
Is an outlet opening. The shape of the chamber 14 may be rectangular, for example.

Inside the chamber 14, a diffusion medium 16 having a known diffusion resistance and having a constant shape is arranged with a uniform thickness so as to close the gas passage between the inlet opening and the outlet opening. In this embodiment, the diffusion medium 16
Is formed by depositing glass beads having a diameter of 0.4 mm. To form the glass bead layer, a wire net 28 is stretched horizontally in the chamber 14. In the present embodiment, the distance between the inlet side 16A and the outlet side 16B of the diffusion medium 16, that is, the thickness of the diffusion medium is 3.3 cm. In FIG. 2, L1 is 156.
mm, L2 is 30 mm, L3 is 75 mm, and L4 is 35 mm. Each of these dimensions is an example, and other dimensions can be adopted.

As the diffusion medium 16, for example, a porous material or the like can be used. In addition, although a liquid can be used, the lower surface must be formed of a semipermeable membrane or the like that allows the gas to be measured to pass therethrough. Similarly, a gas as a diffusion medium can be sealed with two semipermeable membranes or the like.

In any case, the overall shape of the diffusion medium is
In order to prevent the fluctuation of the diffusion resistance, it is necessary to be constant. It is desirable that the diffusion resistance of the diffusion medium is not significantly affected by the surrounding environment, and in that sense, it is desirable to use a solid diffusion medium.

In FIG. 2, a stay 26 is passed across the chamber 14, and the sensor unit 24 is fixed by the stay 26. This sensor unit is composed of a diaphragm 20, an electrolytic solution exposed to the outside through the diaphragm 20 and a protective tube, and a glass electrode immersed in the electrolytic solution.
Via a glass electrode where the gas concentration is measured. Note that a gas concentration sensor corresponding to the type of the gas to be measured is used.

In this embodiment, as the gas concentration on the outlet side of the diffusion medium 16, the gas concentration of the gas in the atmosphere is used for convenience, and the gas concentration difference is calculated as described later. However, as shown by the broken line in FIG. 2, if the gas concentration sensor 22 for measuring the gas concentration on the outlet side is provided and the gas concentration on the outlet side is measured simultaneously with the measurement of the gas concentration on the inlet side, the gas flux can be obtained more accurately. be able to.

In this embodiment, the height H of the wall on the outlet side of the diffusion medium in the chamber 14 is set to several mm in order to allow the gas to diffuse into the atmosphere naturally. If so, the height of the wall can be increased. Further, the height H of the wall on the diffusion medium outlet side in the chamber 14 may be configured to be adjustable according to the influence of the atmosphere or the like.

FIG. 3 shows an example of a gas flux measuring system using the gas flux measuring device 12 described above. A case in which the gas flux of carbon dioxide emitted from soil is measured using this system will be described.

First, the lower end of the chamber 14 is inserted several cm into the soil. Then, carbon dioxide gas from the soil is introduced into the chamber 14. The carbon dioxide gas introduced into the chamber 14 diffuses through the diffusion medium 16,
The gas gradually reaches the outlet side of the diffusion medium 16, and after a certain time (for example, several minutes) elapses, the gas concentration on the inlet side and the gas concentration on the outlet side of the diffusion medium become steady. At that time, the concentration of carbon dioxide on the inlet side is read, and the concentration difference calculating device 30 reads the concentration of carbon dioxide in the atmosphere α (for example, 330 pp) from the concentration of carbon dioxide on the inlet side.
m) is subtracted to obtain a density difference. Here, the concentration difference is, for example, about several hundred to 1,000 ppm. The gas flux calculating device 32 calculates the gas flux of carbon dioxide from soil using the concentration difference and the diffusion resistance value of the diffusion medium stored in the memory 34. Then, the value is displayed on the display 36.

According to the apparatus of this embodiment, since the gas is constantly discharged to the atmosphere, it does not affect, for example, the activity of microorganisms in the soil. Therefore, the device of this embodiment is
This is effective when measuring gas flux continuously over a long period of time. Since the thickness of the diffusion medium affects the response speed of the device, the response can be improved by using a thinner diffusion medium.

[0038]

As described above, according to the present invention,
By introducing a flux into a diffusion medium having a known diffusion resistance, it is not necessary to determine a complicated diffusion resistance every time the flux is measured, and a simple measurement of only a concentration difference measurement can be performed.

If the diffusion resistance of the diffusion medium is sufficiently smaller than that of the object to be measured, the emitted gas flux can be measured accurately without underestimating.

Further, the gas is constantly passed through the diffusion medium,
Since it is transported out of the chamber in the same manner as under natural conditions, it is possible to avoid a change in the source intensity due to an extreme increase (decrease) in the concentration in the chamber.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram illustrating the principle of the present invention.

FIG. 2 is a view showing a gas flux measuring device according to the present invention.

FIG. 3 is a block diagram illustrating a configuration of a gas flux measurement system.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Soil 12 Gas flux measuring device 14 Chamber 16 Diffusion medium

Claims (2)

(57) [Claims] 1. A gas to be measured is passed through a diffusion medium having a known diffusion resistance and a uniform shape, and the gas to be measured is determined using an inlet gas concentration and an outlet gas concentration of the diffusion medium and a diffusion resistance of the diffusion medium. A gas flux measuring method, wherein a gas flux of a measurement gas is obtained. 2. It has a gas inlet opening and a gas outlet opening,
A chamber through which the gas to be measured flows through the internal cavity, and a gas diffusion path provided between the gas inlet opening and the gas outlet opening in the chamber to close the gas flow path, and having a known diffusion resistance and a uniform shape, A gas flux measuring device, comprising: at least one gas concentration sensor installed to determine a gas concentration difference between an inlet side and an outlet side of a diffusion medium.