JP5793033B2 - Combustible gas detection method and detection apparatus - Google Patents

Description

  The present invention relates to a combustible gas detection method and a detection apparatus.

  Conventionally, in underground construction sites, it has been necessary to detect gas leaks from city gas supply pipes buried underground in order to prevent the occurrence of explosion accidents and to improve site safety. However, since methane gas may naturally occur in the ground, it is also necessary to confirm whether the combustible gas detected on the ground surface is due to gas leakage or is naturally generated.

  Thus, as a device for detecting gas leakage from the supply pipe of city gas containing methane as a main component on the surface of the earth, ethane gas, propane gas and butane gas are used as subcomponents for city gas containing methane gas as a main component. Detection means having a function of separating and detecting ethane gas, propane gas, and butane gas (hereinafter collectively referred to as “separation detection target gas”). And when the detection detection target gas is not detected by the detection means, the combustible gas existing on the ground surface is determined not to be caused by gas leakage from the city gas supply pipe but to be naturally generated Are known (for example, see Patent Document 1).

  However, since the apparatus having such a configuration needs to analyze and inspect the gas to be inspected, it is intended to obtain detailed information such as the type (composition) of the combustible gas constituting the gas to be inspected or the amount of combustion heat. In this case, the type of combustible gas must be determined based on the results of the separation analysis, and the amount of combustion heat of the combustible gas must be calculated. It is difficult to carry out a survey over a wide area in a short time because discrimination and the like cannot be performed at the same time.

  In addition, a sensor capable of selectively detecting methane gas and a sensor capable of detecting combustible gas are provided, based on the concentration of methane gas in the gas under test obtained from the difference between the output values of these two sensors. An apparatus having a configuration for determining the type of combustible gas constituting the gas to be inspected has been proposed (see Patent Document 2). In such an apparatus, the combustible gas constituting the gas to be inspected is It can only identify whether it is methane gas, liquefied petroleum gas, or other combustible gas, and therefore the combustible gas that constitutes the gas to be inspected is flammable gas other than methane gas and liquefied petroleum gas. When it is identified, it is difficult to obtain detailed information on the combustible gas such as the type (composition) or the amount of combustion heat.

JP 2004-53404 A JP 2001-141681 A

In the present invention, based on the above circumstances, the present inventors have repeatedly studied on a method for detecting gas leakage from a city gas supply pipe on the ground surface, and combustible gas made of paraffinic hydrocarbon gas. Is a result of finding that there is a correlation between the ratio of density to refractive index and the amount of combustion heat.
The object of the present invention is to detect the combustible gas in the gas to be inspected and to determine the amount of combustion heat of the combustible gas constituting the gas to be inspected, even if the gas to be inspected is mixed with air at an unknown rate. It is an object of the present invention to provide a combustible gas detection method and a combustible gas detection device capable of easily detecting.

The method for detecting a combustible gas according to the present invention measures the refractive index and density of a gas to be inspected which may contain a combustible gas composed of paraffinic hydrocarbon gas collected together with air, and the obtained refraction. The difference Δn (n1−n0) between the refractive index value n1 obtained from the refractive index value n1 and the refractive index value n0 of the air, and the density value d1 obtained from the obtained density value d1. Based on these ratios (Δd / Δn) calculated from the difference Δd (d1−d0) with the density value d0 of
The calorific value of the combustible gas constituting the test gas is obtained from the correlation between the ratio of the density of the combustible gas made of paraffinic hydrocarbon gas to the refractive index obtained in advance and the calorific value of the combustible gas. It is characterized by that.

  In the combustible gas detection method of the present invention, it is preferable that the density value d1 of the test gas is obtained by measuring the sound velocity of the test gas.

The combustible gas detection device of the present invention is a refractive index measurement mechanism for measuring the refractive index of a gas to be inspected that may contain a combustible gas made of paraffinic hydrocarbon gas, collected together with air, It has a density measurement mechanism for measuring the density of the gas to be inspected, and a combustible gas detection mechanism.
Based on the correlation between the ratio of the density of the combustible gas made of paraffinic hydrocarbon gas to the refractive index and the calorific value of the combustible gas, which is acquired in advance. The difference Δn (n1−n0) between the refractive index value n1 of the test gas obtained in the measurement mechanism and the refractive index value n0 of the air, and the density value d1 of the test gas obtained in the density measurement mechanism. By comparing the ratio (Δd / Δn) with the difference Δd (d1−d0) from the air density value d0 in the correlation, the calorific value of the combustible gas constituting the gas to be inspected can be obtained. It has a desired function.

In the method for detecting a combustible gas according to the present invention, in a gas containing a combustible gas made of paraffinic hydrocarbon gas and air, the gas with respect to the difference between the refractive index value of the gas and the refractive index of the air. The ratio of the difference between the density value of air and the density of air is independent of the air content and the content ratio, and the type (composition) of the combustible gas contained, specifically the combustion of the combustible gas By taking advantage of the fact that the ratio is in a certain range according to the amount of heat and the ratio has a correlation with the amount of combustion heat of the combustible gas, the gas to be inspected obtained by the measurement is obtained. Ratio (Δd) of the difference Δn (n1−n0) between the refractive index value n1 and the refractive index value n0 of the air and the difference Δd (d1−d0) between the density value d1 and the air density value d0. / Δn), the combustible gas constituting the gas to be inspected It can be obtained in the amount of combustion heat.
Therefore, according to the method for detecting a combustible gas of the present invention, the refractive index and density obtained by measuring the refractive index and density of the gas to be inspected even if the gas to be inspected is mixed with air at an unknown rate. The difference Δn (n1−n0) from the refractive index value n0 of the air with a value of n1 and the difference Δd (d1−d0) from the value d0 of the air density of the obtained density value d1 are obtained. From the value of these ratios (ratio (Δd / Δn)), the amount of combustion heat can be easily obtained by utilizing the correlation between the ratio of density to the refractive index in the combustible gas made of paraffinic hydrocarbon gas and the amount of combustion heat. In addition, the detection of the combustible gas in the inspection gas is performed on the basis of the value of the combustion heat quantity or the ratio (Δd / Δn), so that the detection of the combustible gas in the inspection gas is performed. And the combustion heat of the combustible gas constituting the gas to be inspected It is possible to perform the detection easily.

  According to the combustible gas detection device of the present invention, the combustible gas detection mechanism provided together with the refractive index measurement mechanism and the density measurement mechanism for measuring the refractive index and density of the gas to be inspected is a paraffinic hydrocarbon. Combustion of combustible gas that constitutes a gas to be inspected based on the method of detecting a combustible gas according to the present invention, by using the correlation between the ratio of density to refractive index and the amount of combustion heat in the combustible gas made of gas Because it detects the amount of heat, even if the test gas is mixed with air at an unknown rate, detection of the combustible gas in the test gas and combustion of the combustible gas constituting the test gas The amount of heat can be easily detected.

It is explanatory drawing which shows an example of a structure of the apparatus used as a density measuring mechanism which comprises the detection apparatus of the combustible gas of this invention. The relationship between the difference between the refractive index value of the gas containing the combustible gas made of paraffinic hydrocarbon gas and the refractive index value of air obtained in Experimental Example 1 and the content ratio of the combustible gas It is a graph which shows. The relationship between the difference between the density value of the gas containing the combustible gas made of paraffinic hydrocarbon gas and the air density value obtained in Experimental Example 1 and the content ratio of the combustible gas is shown. It is a graph. The density of the gas with respect to the difference between the content ratio of the gas containing the combustible gas made of paraffinic hydrocarbon gas and the refractive index value of the gas and the refractive index value of the air obtained in Experimental Example 1 It is a graph which shows the relationship with the value of the ratio of the difference of the value of and the value of the density of air.

  The method for detecting a combustible gas according to the present invention uses a gas that is collected together with air and that may contain a combustible gas made of paraffinic hydrocarbon gas as a test gas. And measuring the refractive index value n1 of the gas to be inspected and the density value d1 of the gas to be inspected, and detecting the amount of combustion heat of the combustible gas constituting the gas to be inspected. It is characterized by this.

  In the method for detecting a combustible gas according to the present invention, a method for detecting the combustion heat quantity of the combustible gas constituting the test gas based on the refractive index value n1 and the density value d1 of the test gas is first measured. The difference Δn (n1−n0) (hereinafter referred to as the refractive index value n1 and the density value d1 of the inspected gas and the refractive index value n0 of the inspected gas and the refractive index value n0 of air) Also referred to as “refractive index difference Δn”) and difference Δd (d1−d0) between the density value d1 of the gas to be inspected and the density value d0 of air (hereinafter also referred to as “density difference Δd”). These ratios, specifically, the ratio of density difference Δd to refractive index difference Δn (Δd / Δn) (hereinafter also referred to as “characteristic value C1”) were obtained, and then obtained. Based on the characteristic value C1 of the gas to be inspected, the fuel made of paraffinic hydrocarbon gas acquired in advance From the correlation between the ratio of the density to the refractive index of the combustible gas and the amount of combustion heat of the combustible gas (hereinafter also referred to as “ratio (density / refractive index) -caloric correlation”), specifically, the ratio (Density / refractive index) -Method of obtaining the combustion heat quantity of the combustible gas constituting the test gas by collating the characteristic value C1 of the test gas against the heat quantity correlation (hereinafter referred to as “specific combustion heat quantity detection”). It is also called “method”.)

Here, the “ratio (density / refractive index) -caloric correlation” in the combustible gas made of paraffinic hydrocarbon gas is a correspondence relationship in which the amount of combustion heat decreases as the ratio of the density to the refractive index increases.
In addition, this “ratio (density / refractive index) -caloric correlation” is the value of the combustion calorific value and the refraction obtained by measurement for each of a plurality of types of paraffinic hydrocarbon gases (combustible gases) with different combustion calorific values. The ratio value calculated from the ratio value and the density value (specifically, the ratio of the density value d to the refractive index value n (d / n)) is obtained. The relationship can be obtained by graphing, for example.
In addition, for each of gases in which air is mixed in a plurality of types of paraffinic hydrocarbon gases (combustible gases) having different calorific values with unknown or known ratios, the paraffinic hydrocarbon gas (combustible gas) constituting the gas is included. ) And the difference between the refractive index value of the combustible gas mixed with air obtained by the measurement and the refractive index value of the air, and the density of the combustible gas mixed with air obtained by the measurement. The ratio value calculated from the difference between the air density value and the air density value (specifically, the air relative to the difference between the refractive index value of the combustible gas mixed with air and the refractive index value of the air) The value of the difference between the density value of the combustible gas mixed with the air density value) and the relationship between these values can be obtained, for example, by graphing.

  In order to carry out such a combustible gas detection method of the present invention, for example, a refractive index measuring mechanism for measuring the refractive index of the gas to be inspected and a density measuring mechanism for measuring the density of the gas to be inspected. Based on the refractive index value n1 obtained in the refractive index measurement mechanism and the density value d1 obtained in the density measurement mechanism, the combustion heat quantity of the combustible gas constituting the test gas by a specific combustion heat quantity detection method The combustible gas detection device of the present invention having a configuration including a combustible gas detection mechanism having a function for obtaining the above can be used.

  As a refractive index measurement mechanism for measuring the refractive index of the gas to be inspected and obtaining the refractive index value n1 of the gas to be inspected, a gas refractometer equipped with a conventionally known refractive index sensor can be used.

As a density measurement mechanism for measuring the density of the gas to be inspected and obtaining the density value d1 of the gas to be inspected, since a highly reliable measurement value can be obtained, the acoustic wave in the gas to be inspected can be obtained. A sound velocity sensor having a configuration obtained by measuring a propagation velocity, that is, a sound velocity of a gas to be inspected, and calculating a density of the gas to be inspected by the following formula (1) based on the obtained sound velocity value. An equipped gas density meter can be used.
Here, in the following formula (1), γ is the specific heat ratio, R is the gas constant, T is the temperature of the gas to be inspected, and c is the speed of sound of the gas to be inspected.

Formula (1):
Density = γRT / c ²

As a specific example of the gas density meter provided with the sonic sensor, for example, a known ultrasonic gas density meter can be cited.
Here, as the ultrasonic gas density meter, for example, there is a configuration including the piezoelectric element 12 as shown in FIG. 1 and obtaining the specific gravity using the resonance frequency of the ultrasonic wave.
The ultrasonic gas density meter of FIG. 1 has one end opened, and a gas discharge port 11B is formed by the opening, and a gas introduction port 11A is provided on the other end side for circulating a gas to be inspected. The measurement tube 10 and a piezoelectric element 12 provided at the other end of the measurement tube 10, and in a state where a gas to be inspected is circulated in the measurement tube 10, ultrasonic waves are transmitted from the piezoelectric element 12 and In this configuration, the ultrasonic resonance frequency is measured by propagating the ultrasonic wave into the measurement tube 10 and the density of the gas to be inspected is obtained based on the sound velocity obtained from the resonance frequency.
In FIG. 1, the arrow indicates the flow direction of the gas to be inspected.

  As the combustible gas detection mechanism, first, the characteristic value C1 of the test gas is obtained from the refractive index value n1 of the test gas obtained in the refractive index measurement mechanism and the density value d1 obtained in the density measurement mechanism. Then, the characteristic value C1 of the inspection gas is collated with a ratio (density / refractive index) -heat quantity correlation acquired in advance to obtain the calorific value of the combustible gas constituting the inspection gas. An apparatus can be used.

  Specific examples of the combustible gas detection mechanism include a personal computer, a recorder with a calculation function, and the like.

  In the combustible gas detection device of the present invention having such a configuration, each of the refractive index measurement mechanism and the density measurement mechanism may contain, for example, a combustible gas together with air collected by the gas sampling means. By supplying a certain gas as the inspection gas, the refractive index value n1 of the inspection gas is obtained in the refractive index measurement mechanism, and the density d1 of the inspection gas is obtained in the density measurement mechanism. In the combustible gas detection mechanism, the characteristic value C1 is calculated from the refractive index value n1 obtained by the refractive index measurement mechanism and the density value d1 of the gas to be inspected obtained by the density measurement mechanism, and the obtained characteristic is obtained. Based on the value C1, the combustion heat quantity of the combustible gas constituting the test gas is obtained from the ratio (density / refractive index) -heat quantity correlation. Further, based on the value of the combustion heat quantity or the characteristic value C1 of the obtained combustible gas, the combustible gas in the test gas is detected. The detection result of the combustion heat quantity and the combustible gas thus obtained is displayed by, for example, a display means.

In the combustible gas detection method of the present invention implemented by the combustible gas detection device having the above-described configuration, the gas to be inspected is air having an unknown ratio with respect to the combustible gas made of paraffinic hydrocarbon gas. The gas is mixed, and the content ratio of air in the test gas may be any ratio.
The method for detecting a combustible gas of the present invention basically uses a gas in which an unknown proportion of air is mixed in a paraffinic hydrocarbon gas as a gas to be inspected. On the other hand, it is also possible to detect the amount of combustion heat of gas in which air is mixed at a known rate.
Furthermore, according to the method for detecting a combustible gas of the present invention, it is also possible to detect the amount of combustion heat of a gas containing only 0% of air, that is, a paraffinic hydrocarbon gas.

In the combustible gas detection method of the present invention as described above, in a gas containing a combustible gas made of paraffinic hydrocarbon gas and air, the difference between the refractive index value of the gas and the refractive index of air. The ratio of the difference between the density value of the gas and the density of the air with respect to the amount of the combustible gas contained, in particular, the combustion, regardless of the air content and the content ratio The ratio of the difference in density with respect to the difference in refractive index is relative to the combustion heat in the combustible gas, specifically, the refraction is refracted. The refractive index value n1 of the gas to be inspected obtained by measurement by utilizing that the ratio of the difference related to the density to the difference related to the rate has a specific correspondence that the combustion heat quantity decreases as the ratio increases Air refractive index Based on the ratio (Δd / Δn) (characteristic value C1) of the difference Δn (n1−n0) from the value n0 and the difference Δd (d1−d0) between the density value d1 and the air density value d0 Thus, the amount of combustion heat of the combustible gas constituting the test gas can be obtained.
As described above, according to the method for detecting a combustible gas of the present invention, even if the test gas is mixed with air at an unknown ratio, the refractive index and density of the test gas are measured and obtained. The difference Δn (n1−n0) between the refractive index value n1 and the refractive index value n0 of the air, and the difference Δ (d1−d0) between the obtained density value d1 and the air density value d0. From the ratio value (ratio (Δd / Δn)), the ratio of the density to the refractive index in the combustible gas made of paraffinic hydrocarbon gas and the correlation with the calorific value (ratio (density / refractive index)) -It is possible to easily obtain the combustion heat quantity by utilizing the heat quantity correlation), and the detection of the combustible gas in the inspection gas is performed based on the combustion heat quantity. And combustion of combustible gas constituting the test gas It is possible to perform detection of the heat easily.

  In the combustible gas detection method of the present invention, the characteristic value C1 used for detecting the combustion heat quantity of the combustible gas constituting the test gas is constant according to the type (composition) of the combustible gas. Since it falls within the range, the type (composition) of the combustible gas constituting the gas to be inspected can be predicted with a certain degree of reliability based on this characteristic value C1 or the obtained value of combustion heat. it can.

  Therefore, the method for detecting a combustible gas according to the present invention includes a method for detecting a combustible gas in a gas to be inspected and a method for detecting the amount of combustion heat of the combustible gas constituting the gas to be inspected. It can also be used as a technique for simply measuring the amount of combustion heat and the type (composition) of natural gas mined from a well for mining natural gas.

Furthermore, the method for detecting a combustible gas of the present invention can be suitably used as a technique for detecting a gas leak from a city gas supply pipe on the ground surface.
That is, according to the method for detecting a combustible gas of the present invention, no matter what kind (composition) of city gas, regardless of whether methane gas is naturally generated in the ground, Gas leakage can be detected reliably.
Specifically, when the gas leakage from the city gas supply pipe is detected by the method for detecting a combustible gas according to the present invention, the gas consists of city gas and / or methane gas collected together with an unknown proportion of air on the ground surface. A gas that may contain a combustible gas is used as a test gas, and the value of the combustion heat of the combustible gas constituting the test gas is 39.94 MJ, which is the combustion heat of methane gas. If detected, the flammable gas constituting the gas to be inspected is only methane gas, and no gas leaks from the city gas supply pipe, while the combustible gas constituting the gas to be inspected. When it is detected that the combustion calorific value of the gas is a value other than 39.94 MJ, which is the combustion calorific value of tan gas, the city gas is the only combustible gas that constitutes the gas under test. That, or a mixed gas of city gas and methane gas, it is confirmed that the gas leakage from the supply pipe of city gas is generated.
Further, when it is detected that the value of the combustion heat of the combustible gas constituting the test gas is a value other than 39.94 MJ which is the combustion heat of methane gas, it is based on the value of the detected combustion heat. Therefore, it is possible to confirm whether the combustible gas constituting the gas to be inspected is only city gas or a mixed gas of city gas and methane gas, that is, a gas leak from the city gas supply pipe occurs. The presence or absence of generation of methane gas in the ground at the location where it is located can be easily confirmed.

Although the method for detecting a combustible gas according to the present invention has been specifically described above, the present invention is not limited to the above example, and various modifications can be made.
For example, the method for detecting a combustible gas is not limited to being performed by an apparatus including a refractive index measuring mechanism, a density measuring mechanism, and a combustible gas detecting mechanism, and the refractive index value n1 of the gas to be inspected. If the characteristic value C1 of the gas to be inspected is calculated from the density value d1 and the amount of combustion heat of the combustible gas constituting the gas to be inspected is detected based on the characteristic value C1, the refractive index of the gas to be inspected The apparatus for obtaining the value n1 and the density value d1 may not be integrated but may be separate, and the method for calculating the characteristic value C1 of the gas to be inspected is automatic calculation by an arithmetic unit or the like. Alternatively, the calculation by the method may be performed, and the method for obtaining the value of the combustion heat quantity based on the characteristic value C1 may be an automatic calculation by a computing machine or the calculation by the method.

  Hereinafter, experimental examples of the present invention will be described.

[Experimental Example 1]
The combustible gas is a methane gas having a combustion heat quantity of 39.94 [MJ / Nm ³ ], a mixed gas of methane gas and ethane gas, the volume ratio (methane gas: ethane gas) is 92: 8, and the combustion heat quantity is 42. 4 [MJ / Nm ³ ] (hereinafter also referred to as “combustible mixed gas (1)”), a mixed gas of methane gas and ethane gas, with a volume ratio (methane gas: ethane gas) of 83.5: A gas having a combustion heat amount of 45.0 [MJ / Nm ³ ] (hereinafter also referred to as “combustible mixed gas (2)”), a mixed gas of methane gas and propane gas, A gas having a volume ratio (methane gas: propane) of 91.8: 8.2 and a combustion heat amount of 44.9 [MJ / Nm ³ ] (hereinafter also referred to as “combustible mixed gas (3)”) and [MJ with combustion heat of 45.0 Were prepared Nm ^3] compressed natural gas (CNG).
These five types of flammable gases, and mixed gas of the five types of flammable gases and air, the content ratio (volume ratio) of the flammable gas is 20%, 40%, 60% and 80% A gas is used as a sample gas, and each of the sample gases is measured for a refractive index and a density using a gas refractometer equipped with a refractive index sensor and a gas density meter equipped with a sonic sensor, and the obtained refractive index. And the density value of the sample gas, the difference between the refractive index value of the sample gas and the refractive index value of the air (hereinafter also referred to as “refractive index difference”) and the density value of the sample gas. The difference from the value (hereinafter also referred to as “density difference”) was calculated.
And based on the values of the obtained refractive index difference and density difference, for each of the five types of combustible gas, the relationship between the content ratio of the combustible gas and the refractive index difference in the gas containing the combustible gas, And the relationship between the content ratio of combustible gas and density difference was confirmed. The results are shown in FIG. 2 and FIG.
Further, the ratio of density difference to refractive index difference (density / refractive index) was calculated for each sample gas. The results are shown in FIG.
Here, in FIG. 2, the refractive index difference is a relative value based on the refractive index difference of methane gas (100%). In FIG. 3, the density difference is a relative value based on the density difference of methane gas (100%). In FIG. 4, the vertical axis represents the value of the density difference ratio relative to the refractive index difference, and the horizontal axis represents the combustible gas content ratio, and the combustible gas content ratio is a refractive index related to the gas refractometer. It is shown based on the output value of the rate sensor (relative value based on the refractive index difference of methane gas).
2 to 4, values relating to methane gas are indicated by rhombus plots (♦), values relating to combustible mixed gas (1) are indicated by square plots (□), and combustible mixed gas (2 ) Is indicated by a circle plot (◯), a value relating to the combustible gas mixture (3) is indicated by a triangular plot (Δ), and a value relating to the compressed natural gas is indicated by a cross plot (×).

From the results of FIG. 2, in the mixed gas of combustible gas and air made of paraffinic hydrocarbon gas, the refractive index difference changes proportionally according to the content ratio of the combustible gas. When the content ratio of the combustible gas increases, the refractive index difference increases proportionally, and when the calorific value of the combustible gas increases, the refractive index difference increases, that is, when the combustible gas content ratio is the same. It was confirmed that the difference in refractive index increases as the combustible heat quantity of the combustible gas constituting the mixed gas increases.
Further, from the result of FIG. 3, in the mixed gas of combustible gas and air made of paraffinic hydrocarbon gas, the density difference changes proportionally according to the content ratio of the combustible gas, specifically, When the content ratio of the combustible gas increases, the density difference increases proportionally, and as the calorific value of the combustible gas increases, the density difference decreases, that is, when the content ratio of the combustible gas is the same. It was confirmed that the density difference decreases as the combustible heat quantity of the combustible gas constituting the mixed gas increases.
Further, from the results of FIG. 4, the ratio of the density difference to the refractive index difference is constant regardless of the air content ratio, as long as the amount of combustion heat is constant, even if the composition of the combustible gas is different. It was confirmed that the value was within the range and became smaller as the amount of combustion heat increased.

10 Measurement tube 11A Gas inlet 11B Gas outlet 12 Piezoelectric element

Claims (3)

Measure the refractive index and density of the test gas that may be collected with air and contain a combustible gas composed of paraffinic hydrocarbon gas, and obtain the refractive index obtained from the obtained refractive index value n1. The difference Δd () between the difference Δn (n1−n0) of the refractive index value n0 of the air having the value n1 and the air density value d0 of the density value d1 obtained from the obtained density value d1. d1-d0) based on these ratios (Δd / Δn)
The calorific value of the combustible gas constituting the test gas is obtained from the correlation between the ratio of the density of the combustible gas made of paraffinic hydrocarbon gas to the refractive index obtained in advance and the calorific value of the combustible gas. A method for detecting a combustible gas.   The combustible gas detection method according to claim 1, wherein the density value d <b> 1 of the inspection gas is obtained by measuring a sound velocity of the inspection gas. Refractive index measurement mechanism for measuring the refractive index of a test gas that may contain a combustible gas consisting of paraffinic hydrocarbon gas collected with air, density for measuring the density of the test gas It has a measurement mechanism and a combustible gas detection mechanism.
Based on the correlation between the ratio of the density of the combustible gas made of paraffinic hydrocarbon gas to the refractive index and the calorific value of the combustible gas, which is acquired in advance. The difference Δn (n1−n0) between the refractive index value n1 of the test gas obtained in the measurement mechanism and the refractive index value n0 of the air, and the density value d1 of the test gas obtained in the density measurement mechanism. By comparing the ratio (Δd / Δn) with the difference Δd (d1−d0) from the air density value d0 in the correlation, the calorific value of the combustible gas constituting the gas to be inspected can be obtained. A combustible gas detection device characterized by having a required function.