JP2018169263A - Method and device for identifying gaseous species and method for measuring gas concentration - Google Patents

Abstract

To provide a method for identifying gaseous species in a sample gas by determining the concentration of each component of a city gas and an LPG gas that can be found in the sample gas and by knowing the concentration of each gas.SOLUTION: The identification is made based on the measured value x of the ethane concentration in a sample gas, the measured value y of the propane concentration, the composition ratio a between the ethane concentration xand the propane concentration yof the city gas that can be found in the sample gas, the ethane concentration xand the propane concentration yin the city gas in the sample gas obtained based on the composition ratio b between the ethane concentration xand the propane concentration yin the LPG that can be found in the sample gas, and the ethane concentration xand the propane concentration yin the LPG in the sample gas.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a gas type identification method for detecting city gas, LPG, and naturally-occurring methane in a sample gas to detect a gas type in the gas, an identification device for the same, and a gas concentration for measuring the concentration of each gas. It relates to the measurement method.

  City gas pipes are buried in the soil and are not exposed to the outside air. However, gas leak accidents may occur due to aging of gas transport pipes. Therefore, it is desired to detect when a slight gas leak occurs and minimize the influence of an accident caused by the gas leak. When detecting this gas leak, it is not efficient to dig up and detect the gas transport pipe suddenly because the gas leak is rare. Therefore, a method is adopted in which even a slight gas leak is discovered on the ground surface, and when a certain amount of gas leak is confirmed on the ground surface, it is dug up to the underground gas transport pipe and examined.

In this case, the gas generated from the ground includes methane generated by fermentation of organic matter. Therefore, for example, Patent Document 1, such a fermentation gas, since it involves the generation of CO _2, the amount of CO ₂ is also detected to identify methane by the relevant fermentation gas and its CO _2, other It is disclosed that the presence of city gas or LPG is detected in distinction from city gas or LPG.

Japanese Patent No. 2682882

Methane is not only contained in city gas and fermentation gas, but may also include natural gas generated in the lower part of the ground, methane fermentation in the ground, gas fields, and other derived methane. Therefore, as in the above-mentioned Patent Document 1, by detecting CO ₂ , it is possible to distinguish methane contained in city gas from other methane when methane other than methane by fermentation is contained. There is a problem that is not accurate.

  An object of the present invention is to provide a gas type identification method for determining the concentration of each composition of city gas and LPG that may be present in a sample gas and identifying each gas.

  Another object of the present invention is to provide a gas concentration measuring method and a gas concentration measuring device for determining the concentration of city gas and LPG in a sample gas by determining the concentration of each composition in the city gas and LPG. It is in.

The gas species identification method according to the first embodiment of the present invention is a method for identifying gas species of city gas, LPG, and naturally occurring methane in a sample gas, and measuring the ethane concentration x in the sample gas. Value, measured value of propane concentration y, ratio a of ethane concentration x _{1 of} city gas that can exist in the sample gas and propane concentration y ₁ , ethane concentration x _{2 of} LPG that can exist in the sample gas and propane was calculated based on the ratio b between the concentration y _2, on the basis the ethane city gas concentration x ₁ propane concentration y ₁ in the sample gas, and LPG ethane concentration x ₂ and propane concentration y ₂ of the sample gas Identified.

The gas concentration measurement method according to the second embodiment of the present invention is a method for measuring the concentrations of city gas, LPG, and naturally-occurring methane gas in a sample gas, the ethane concentration x in the sample gas Measured value of propane, measured value of propane concentration y, measured value of methane concentration z, ratio a of ethane concentration x _{1 of} city gas and propane concentration y ₁ that may exist in the sample gas, ethane concentration x of city gas ₁ of methane concentration z ₁ and ethane of city gas in the sample gas calculated based on the ratio c of ethane concentration x _{2 of} LPG and propane concentration y _{2 of} LPG which may be present in the sample gas The concentration of each gas in the sample gas is detected by the concentration x ₁ , the propane concentration y _{1, the} methane concentration z ₁ , the ethane concentration x ₂ of LPG in the sample gas, and the propane concentration y ₂ .

  A gas concentration measuring apparatus according to a third embodiment of the present invention is a gas type identifying apparatus for identifying each gas type of city gas, LPG, and naturally occurring methane in a sample gas, and comprising ethane in the sample gas A separation column that separates gas components of propane and methane, a concentration detector that detects concentrations of the ethane, propane, and methane gases, a measured value of the ethane concentration, a measured value of the propane concentration, and the sample Based on the ratio of the ethane concentration of the city gas that can be present in the gas to the propane concentration, and the ratio of the ethane concentration of LPG that can be present in the sample gas to the propane concentration, the ethane of the city gas in the sample gas Calculation means for calculating the concentration and propane concentration, and the ethane concentration and propane concentration of LPG in the sample gas.

  According to the present invention, since the concentration of each composition of city gas and LPG can be detected, the presence or absence of each gas can be easily identified.

It is a flowchart which shows an example of the method of identifying the gas type of the 1st Embodiment of this invention. It is a figure which shows the structural example of the identification device of the gas type of the 3rd Embodiment of this invention. It is a figure which shows the other structural example of the identification device of the gas type of the 3rd Embodiment of this invention.

Next, a gas type identification method according to an embodiment of the present invention will be described with reference to the drawings. As shown in the flowchart of an example in FIG. 1, the gas type identification method according to an embodiment includes a measured value x of ethane concentration in a sample gas, a measured value y of propane concentration, and a city that can exist in the sample gas. The city in the sample gas calculated based on the ratio a between the ethane concentration x _{1 of the} gas and the propane concentration y ₁ and the ratio b of the ethane concentration x _{2 of} LPG and the propane concentration y ₂ that may exist in the sample gas. Identification is made based on the ethane concentration x ₁ and propane concentration y _{1 of} the gas, and the ethane concentration x ₂ and propane concentration y ₂ of LPG in the sample gas.

That is, the composition ratio of city gas and LPG may differ depending on the production area.
(A) The composition ratio of methane, ethane, and propane in city gas and LPG produced under the same conditions as the raw material in the same production area is always constant,
(B) The composition ratio of ethane and propane in the LPG is constant. In the LPG for household use and business use, the propane content is 95% or more, and its content β is almost constant, and the propane / ethane ratio is constant. , LPG should not contain methane,
(C) Spontaneous methane contains methane produced by methane fermentation and other methane, but contains almost no ethane or propane,
(D) City gas contains miscellaneous gas in addition to methane, ethane, and propane. The miscellaneous gas content α is always constant (approximately 2%).
The present inventor noticed that there is a certain rule and completed the present invention based on the rule. If the city gas or LPG production location at the sample gas measurement location is unknown and the composition ratio is unknown, the city gas and LPG gas handled in the vicinity of the measurement location can be measured and analyzed. Each composition ratio can be easily understood.

The ethane concentration x, the propane concentration y, and the methane concentration z in the sample gas can be measured by, for example, an ethane concentration detector, a propane concentration detector, a methane concentration detector using a gas sensor sensitive only to the gas. Assuming that the ethane concentration in city gas is x ₁ , the propane concentration is y ₁ , the methane concentration is z ₁ , the ethane concentration in LPG is x ₂ , the propane concentration is y ₂ , and the methane concentration of naturally occurring methane is z _3. From the findings (b) to (d), the following equations (1) to (3) are obtained.
Ethane concentration x = x ₁ + x ₂ (1)
Propane concentration y = y ₁ + y ₂ (2)
Methane concentration z = z ₁ + z ₃ (3)

On the other hand, the following expressions (4) to (6) are obtained from the above-described knowledge (a).
x ₁ / y ₁ = a (constant) (4)
x ₂ / y ₂ = b (constant) (5)
x ₁ / z ₁ = c (constant) (6)

In each of the above equations, the unknowns are x ₁ , x ₂ , y ₁ , y ₂ , z ₁ , z ₃ , but since there are six relational expressions, these values are all obtained by simultaneous equations. That is,
_{x 1 = a (by-x} ) / (b-a) (7)
_{x 2 = b (x-ay} ) / (b-a) (8)
_{y 1 = (by-x)} / (b-a) (9)
_{y 2 = (x-ay)} / (b-a) (10)
_{z 1 = a (by-x} ) / {c (b-a)} (11)
z ₃ = z−a (by−x) / {c (b−a)} (12)

From each of the above compositions, the concentration Ct of city gas, the concentration Cp of LPG, and the concentration Cm of naturally occurring methane are obtained as in the following equations (13) to (15).
City gas concentration Ct = (x ₁ + y ₁ + z ₁ ) / (1−α)
= X ₁ (1 + 1 / a + 1 / c) / (1-α) (13)
LPG concentration Cp = y ₂ / β = (x−ay) / {β (b−a)} (14)
Naturally occurring methane concentration Cm = z ₃ = za (by-x) / {c (ba)} (15)

  Therefore, the city gas concentration Ct, LPG concentration Cp, and naturally occurring methane concentration Cm thus determined are the minimum concentrations that are judged to be present in the sample gas (specified values that can avoid misidentification due to measurement errors). If it is above, it will be determined that these gases exist. For example, s is the concentration of the minimum specified value of city gas, t is the concentration of the minimum specified value of LPG, and p is the concentration of the minimum specified value of naturally occurring methane. ) Is greater than or equal to each specified value, and if it is greater than or equal to the specified value, it can be determined that the gas is present in the sample gas. The concentration that is the minimum specified value of each gas can be determined as appropriate. For example, the concentration can be determined based on safety-related regulations held by the user who uses the measurement apparatus, the measurement method, and the identification method.

On the other hand, for example, the composition of city gas is the composition shown in the above (d), and the ratio of each is also known. For example, it is known that the concentration of ethane in city gas is about 6% of city gas. Therefore, instead of the minimum specified value s of city gas, the minimum concentration of ethane of city gas can be set as the specified value. Therefore, the presence or absence of city gas can be determined from the ethane concentration x ₁ . Specifically, the minimum concentration s of city gas may be the minimum specified value of ethane, where 0.06 s = q of ethane in city gas.

Specifically, the minimum specified value concentration s of city gas is based on the above-mentioned knowledge that the ethane concentration in city gas is about 6%, and the minimum specified value concentration of ethane in city gas is 0. 0.06s = q, and q is a specified value for determining the presence or absence of ethane concentration x ₁ for determining the presence or absence of city gas. Therefore, the presence / absence of city gas can be determined by determining whether or not the ethane concentration x ₁ in the city gas determined by the above equation (7) is equal to or greater than the specified value q. The same applies to LPG, and it has been found that the propane concentration in LPG is a content ratio β of 95% or more, and the minimum specified value concentration t of LPG is, for example, the lowest propane concentration y _{2 in} LPG. Whether or not LPG is present can be determined based on whether or not the concentration y ₂ of propane in the LPG is equal to or higher than the specified value r, with the limit specified value r = βt (0.95 ≦ β <1).

In this case, it is assumed that the measured propane concentration y is larger than the propane concentration of the city gas that may exist in the sample gas. Therefore, it must first be examined that x ₁ / y <x ₁ / y ₁ = a. That is, if the ratio (x ₁ / y) of the calculated ethane concentration x ₁ and propane concentration y is smaller than a, it was measured from the propane concentration y ₁ balanced with the ethane concentration x ₁ constituting the city gas. The concentration of propane will be high, and propane other than city gas will be present. Then, it can be determined whether or not LPG is present by determining whether or not the concentration of propane other than city gas is greater than or equal to the specified value r. The reason why the calculated ethane concentration x ₁ is used instead of the measured ethane concentration x is that, depending on the LPG, the ethane concentration x may be abnormally high.

As for the concentration of the naturally occurring methane, the methane concentration z ₃ in the naturally occurring methane becomes the concentration Cm of the naturally occurring methane as it is. Therefore, the minimum specified value of Cm is equal to the minimum specified value of the methane concentration z ₃ in naturally occurring methane, and the value can be set as p. In the presence or absence of the naturally occurring methane, as in the case of propane described above, first, it is checked whether or not the measured methane concentration z is larger than the methane concentration in the city gas. Thereafter, it is examined whether or not the concentration of methane other than city gas is equal to or higher than the above-mentioned predetermined specified value p. In order to check whether there is methane other than methane constituting the city gas, the ratio (x ₁ / z) between the calculated ethane concentration x ₁ and the methane concentration z is x ₁ / z ₁ = c. You can check whether it is small or not. As in the case of propane, if the measured value of the methane concentration z is larger than the methane concentration z ₁ corresponding to the ethane concentration x ₁ constituting the city gas, methane other than the city gas is present. Because. Thereafter, it is examined whether or not the methane concentration z ₃ other than city gas is equal to or higher than a specified value p. Note that the calculated ethane concentration x ₁ is used instead of the measured ethane concentration x because the ethane concentration x may increase in the presence of city gas and LPG. is there.

In the present embodiment, as described above, not only the concentration x ₁ , y ₁ , x ₂ , y ₂ of the composition of city gas, LPG, etc., but also the concentration of city gas Ct, the concentration of LPG, and the concentration of naturally occurring methane Since it is determined, it is possible to determine the presence or absence of these by the specified values. From the above viewpoint, the ethane concentration x _{1 in} city gas and the propane concentration y _{2 in} LPG are more than the specified values. The combination of each gas can be determined by determining whether or not there is. Ethane concentration x ₁ of the city gas, propane concentration y ₂ in the LPG is an example of determining whether there are respectively specified value or more, the identification method of a mixture of gas species in the sample gas, see Figure 1 Further details will be described.

  First, the ethane concentration x and the propane concentration y in the sample gas are measured (S1). At this time, if the methane concentration z is also measured, it is convenient to obtain the concentration of naturally occurring methane later. However, although not essential at this point, in this embodiment, the methane concentration z is also measured.

Next, when city gas is present, the ethane concentration in city gas is x ₁ , the propane concentration is y ₁ , and when LPG is present, the ethane concentration in LPG is x ₂ and the propane concentration is y ₂ . by the aforementioned formula (7) ~ (10), x 1, x 2, y 1, y 2 are determined by calculating (S2).

Thereafter, the concentration z ₃ of naturally occurring methane is determined (S3). If the methane concentration is not measured in step S1, the methane concentration z is measured in step S3. The naturally occurring methane concentration z ₃ is z ₃ = z−z ₁ , and is obtained from the equation (6) as z ₃ = z−x ₁ / c (S3). It is also obtained by z ₃ = z−a (by−x) / {c (b−a)} in the above equation (12). However, in the present embodiment, since the value of already x ₁ is calculated, the better to use the x ₁ is easily determined.

  Next, it is determined whether or not the measured value of the methane concentration z is greater than or equal to the specified value p (S4). The measured value of the methane concentration z can be the sum of the methane concentration in city gas and the methane concentration in naturally occurring methane. It is examined whether the measured methane concentration z includes at least one of city gas or naturally occurring methane. Therefore, in step S4, it is determined whether or not the concentration p is equal to or higher than a minimum specified value at which it is recognized that naturally occurring methane is detected. This specified value p is the minimum concentration at which it can be determined that naturally occurring methane is present, but the methane concentration of city gas is very high (88% of the city gas concentration), so the presence of either is confirmed. In addition, the presence or absence of the naturally occurring methane is determined based on the minimum value.

If it is confirmed in step S4 that some kind of methane is contained (Y in S4: yes), the ethane concentration x ₁ in the city gas when there is city gas is the minimum at which the presence of city gas can be recognized. It is checked whether or not the ethane is equal to or more than the prescribed value q (S5). In the case of Y in step S5, it is determined that city gas exists. The ethane concentration x ₁ in the city gas is obtained in the above-described step S2.

If it is found that city gas exists, the concentration Ct of the city gas is calculated using the formula Ct = (x ₁ + y ₁ + z ₁ ) / (1−α) and z ₁ = x ₁ / c. The Of course, it may be obtained using the above-described equation (13) (S6). This is because x ₁ and y ₁ are obtained in step S2. Here, as described above, α is a ratio of other gases that may exist in city gas, and the composition ratio of other gas species is unknown, but as described above, other gases contained in city gas It is known that the ratio is always constant, for example, about 2%. Since the concentration in the portion (1-α) excluding this miscellaneous gas is (x ₁ + y ₁ + z ₁ ), the concentration Ct of the city gas as a whole is Ct = x ₁ (1 + 1 / a + 1 / c) / It is obtained by (1-α).

Next, the presence or absence of naturally occurring methane is determined. As described above, this determination is made based on whether or not the measured methane concentration z is larger than the methane concentration z ₁ in the city gas and the difference is not less than a specified value p. Therefore, x ₁ / z <c, and the concentration of naturally occurring methane z ₃ = z−z ₁ = z−x ₁ / c is not less than a specified value p that indicates the minimum at which the presence of naturally occurring methane can be confirmed. (S7). In step S4 described above, whether or not the methane concentration z is greater than or equal to the specified value p is examined. Since the methane concentration z may include the methane concentration z ₁ in the city gas, It is examined whether or not the methane concentration z−z ₁ = z−x ₁ / c obtained by subtracting the methane concentration z ₁ in the gas is equal to or greater than the specified value p. However, since z ₃ is obtained in step S3 described above, it may be checked immediately after that whether or not the methane concentration z ₃ of the naturally occurring methane is equal to or higher than the specified value p. However, in this case, if naturally occurring methane is not detected, the determination in steps S5 and S9 is necessary.

If the presence of naturally occurring methane is determined, its concentration Cm is determined by Cm = z ₃ = z−x ₁ / c (S8). Although it may be obtained by calculation of Cm = z−a (by−x) / {c (b−a)} shown in the above equation (15), since z and x ₁ have already been obtained, Cm It is easier to use = z−x ₁ / c.

Next, it is determined whether or not LPG exists. As described above, this determination is made based on whether or not the measured propane concentration y is larger than the propane concentration y ₁ in the city gas and the difference is not less than the specified value r. Therefore, x ₁ / y <x ₁ / y ₁ = a, and the propane concentration in the LPG y ₂ = y−y ₁ = y−x ₁ / a is the minimum specified value that allows the presence of LPG It is determined whether or not the propane concentration corresponding to is equal to or greater than a specified value r (S9). In this case, since x ₂ / y ₂ <x ₁ / y ₁ , x ₁ / y <x / y <x1 / y1 = a. Therefore, instead of x1 / y <a, x / y < It may be determined by a. Since x _{1 in} this equation has already been obtained by the above equation (7), it can be easily calculated. However, y ₂ = (x−ay) / (b−a) may be calculated according to the above-described equation (10).

If Y in step S9, LPG is present, and its concentration Cp is obtained by Cp = y ₂ / β (S10). This Cp may also be obtained by Cp = (x−ay) / {β (b−a)} shown in the above-described equation (14). However, since the value of y ₂ has already been obtained from equation (10), it can be easily obtained by using that value.

  If all the determinations in the above steps are Y, it is determined that the sample gas is a gas derived from all of city gas, LPG, and naturally occurring methane. In addition, the concentration Ct of city gas, the concentration Cp of LPG, and the concentration Cm of naturally occurring methane in the sample gas are obtained.

If the measured value of the methane concentration z is less than the specified value p in step S4 (in the case of N (no) in S4), neither city gas nor naturally generated methane exists. Then, it is checked whether the propane concentration y (measured value) in the sample gas is equal to or higher than the minimum specified value r of the propane concentration in the LPG (S11). Here, the measured value of the concentration of propane in the sample gas is compared with the minimum prescribed value r of propane in LPG. This is because it is determined in step S4 that there is no city gas, so the propane concentration y ₁ in the city gas is 0 and y = y ₂ .

  In the determination of step S11, in the case of Y, only LPG is present, and it can be seen that the sample gas contains gas derived from LPG. In the case of N in step S11, it is determined that none of the city gas, LPG, and naturally occurring methane is included, and it is determined that the sample gas can be ignored as the atmosphere. In the case of Y in step S11, the LPG concentration Cp is obtained in the same manner as in step 10 described above, but is omitted in FIG.

Next, in the case of N in step S5, no city gas exists. In this case, it is determined whether or not the propane concentration y (measured value) is equal to or greater than the specified value r (S12). Also in this case, the measured value of the propane concentration y is compared with the specified value r for the same reason as in step S11. The reason is the same as the description of the step S11 described above, may be compared with y _2.

If the propane concentration y is greater than or equal to the prescribed value r in step S12 (Y in S12), the measured methane concentration z is greater than or equal to the prescribed value of methane in step S4, but the presence of city gas. Even if it is not determined, it may contain some city gas methane (methane below the reference value). Therefore, it is checked whether x ₁ / z <c and z ₃ = z−z ₁ = z−x ₁ / c ≧ p (S13). In this case, when a high concentration of LPG is contained in the sample gas, x / z ≧ c can be satisfied, so the ethane concentration x ₁ is used. When naturally occurring methane is included (Y in S13), it indicates that the sample gas includes a mixed gas of LPG and a gas derived from naturally occurring methane, and the sample gas is a mixture of LPG and naturally occurring methane. It is determined that a mixed gas is contained. In the case of N in step S13, it is determined that the sample gas includes a gas derived only from LPG.

  If y is less than r in step S12 (N in S12), the presence or absence of naturally occurring methane is confirmed (S14), and the presence of naturally occurring methane is confirmed as described above. (In the case of Y in S14), only the naturally occurring methane is present, and it is determined that the sample gas includes only a gas derived from the naturally occurring methane. When the presence of naturally occurring methane is not confirmed in the same manner as described above in step S14 (N in S14), it is ignored as the atmosphere. In addition, when this LPG and naturally occurring methane are included, although omitted in FIG. 1, these concentrations can be obtained by the same formula as described above. The same applies to the following description.

In step S7, when z ₃ is less than p (in the case of N in S7), that is, when naturally occurring methane is not included, the process proceeds to step S15, and whether x ₁ / y <a is satisfied, It is checked whether y ₂ = y−x ₁ / a is equal to or greater than a specified value r. When y ₂ is equal to or greater than the specified value (Y in S15), the sample gas includes a gas derived from city gas and a gas derived from LPG. That is, it is determined that the sample gas includes city gas and LPG. If y ₂ is less than r in step S15 (N in S15), it is determined that this sample gas contains only gas derived from city gas. Since x ₁ / y ₁ ≧ x ₂ / y ₂ , x ₁ / y <x / y = (x ₁ + x ₂ ) / (y ₁ + y ₂ ) <x1 / y1 = a is established. Therefore, it can be determined by x / y <a instead of the aforementioned x ₁ / y <a.

  If LPG is not included in step S9 (N in S9), it is determined that this sample gas includes a gas derived from city gas and a gas derived from naturally occurring methane.

In the embodiment shown in FIG. 1 above, for example, in the case of city gas, the composition of the city gas is used to confirm that the concentration is not less than a specified value that is the minimum concentration that can be recognized as the presence of city gas and LPG. the concentration of certain ethane x ₁ has been determined by whether or not the at prescribed value q more. Further, in the case of LPG, it was determined whether or not the concentration y _{2 of} propane as the composition was not less than the minimum specified value r. However, in the present embodiment, since the city gas concentration Ct and the LPG concentration Cp are obtained, whether or not the calculated concentrations of the city gas and LPG are directly greater than or equal to the prescribed value s, or greater than the prescribed value t. It may be determined whether or not. And if each is above a regulation value, it can be judged that the gas exists in the above-mentioned sample gas with the calculated concentration.

  In the above-described example, the determination of the presence / absence of city gas, the presence / absence of naturally occurring methane, and the presence / absence of LPG in steps S5, S7, and S9 is not defined, and the order of determination may be changed.

  As described above, according to the present embodiment, based on the basic facts (a) to (d) described above, based on the measured values of ethane, propane, and methane that can be easily measured together with these relationships. Thus, the concentration for each component of city gas and the concentration for each component in LPG are required. Therefore, it can be easily determined whether or not each composition exists. And the density | concentration of each gas kind is also calculated | required easily. As a result, what kind of gas is detected in the measurement atmosphere can be easily displayed on the measuring apparatus, and if necessary, the concentration for each gas can be easily displayed.

The gas concentration measurement method according to the second embodiment of the present invention is a method for measuring the concentrations of city gas, LPG, and naturally occurring methane in the sample gas as shown in FIG. It is. Specifically, the ethane concentration x and the propane concentration y in the sample gas are measured by the same method as described above. Then, a composition ratio a between the ethane concentration x ₁ and the propane concentration y ₁ of the city gas that can exist in the sample gas, and a composition ratio b of the ethane concentration x ₂ and the propane concentration y ₂ of the LPG that can exist in the sample gas. The concentration of each gas in the sample gas by the ethane concentration x ₁ and propane concentration y ₁ of the city gas and the ethane concentration x ₂ and propane concentration y ₂ of LPG in the sample gas calculated based on Is detected. This calculation formula is as described above.

Furthermore, the gas concentration measuring apparatus according to the third embodiment of the present invention includes an ethane concentration detector 11 that detects an ethane concentration x in a sample gas, and a sample as shown in a simple block diagram in FIG. Propane concentration detector 12 for detecting propane concentration y in gas, measured value of ethane concentration x, measured value of propane concentration y, ethane concentration x ₁ and propane concentration y _{1 of} city gas that may exist in sample gas Ethane concentration x ₁ and propane concentration y ₁ of the city gas in the sample gas, and the ratio b of ethane concentration x _{2 of} LPG and propane concentration y ₂ that may be present in the sample gas, and An arithmetic means (circuit) 14 for calculating the ethane concentration x ₂ and the propane concentration y ₂ of LPG in the sample gas is provided.

  In the example shown in FIG. 2, the methane detector 13 for detecting the methane concentration is also included, but it is not always essential. That is, when obtaining the concentration of naturally occurring methane, it is necessary to have the methane concentration detector 13, but when it is not necessary, it may be omitted. In addition, as an ethane detector, a propane detector, a methane detector, etc., the gas sensor etc. which are sensitive only to each of ethane, propane, and methane can be used, for example. Moreover, as a calculation means, although it calculates with a microcomputer, PC, etc., a separate circuit may be used.

  In FIG. 2 described above, an example in which the detector and the concentration measurement are performed by separate devices is shown. For example, an example of XG-100 (trade name of New Cosmos Electric Co., Ltd.) is shown in FIG. Gas detection and concentration measurement can be simultaneously performed using a gas chromatography in which a gas component separation column 21 and a gas concentration detector (sensor) 22 are combined.

11 ethane detector 12 propane detector 13 methane detector 14 computing means

Third embodiment of a gas species identification apparatus of the present invention, city gas in the sample gas, a gas species identification device that identifies each type of gas LPG, and naturally occurring methane, of the sample gas Separation column for separating gas components of ethane, propane and methane, a concentration detector for detecting the concentration of each gas of ethane, propane and methane, a measured value of the ethane concentration, a measured value of the propane concentration, Based on the ratio of the ethane concentration of the city gas that may be present in the sample gas to the propane concentration, and the ratio of the ethane concentration of LPG that may be present in the sample gas to the propane concentration, the concentration of the city gas in the sample gas Calculation means for calculating ethane concentration and propane concentration, and ethane concentration and propane concentration of LPG in the sample gas are provided.

Claims (8)

A method for identifying gas species of city gas, LPG, and naturally occurring methane in a sample gas, comprising:
Measured value of ethane concentration x in the sample gas, measured value of propane concentration y, ratio a between ethane concentration x ₁ and propane concentration y _{1 of} city gas that may exist in the sample gas, present in the sample gas The ethane concentration x ₁ and propane concentration y ₁ of city gas in the sample gas, and the ethane of LPG in the sample gas calculated based on the ratio b of the ethane concentration x ₂ and propane concentration y ₂ of LPG gas species identification method based on the concentration x ₂ and propane concentrations y _2. The ethane concentration x of the measurement value is x = x ₁ + x ₂ , and the propane concentration y of the measurement value is y = y ₁ + y ₂ , from x ₁ / y ₁ = a, x ₂ / y ₂ = b ,
_{x 1 = a (by-x} ) / (b-a)
_{x 2 = b (x-ay} ) / (b-a)
_{y 1 = (by-x)} / (b-a)
y ₂ = (x−ay) / (b−a)
The gas type identification method according to claim 1, which is obtained as follows. A method for measuring the concentration of city gas, LPG, and naturally occurring methane gas in a sample gas,
The measured value of ethane concentration x in the sample gas, the measured value of propane concentration y, the measured value of methane concentration z, the ratio a of the ethane concentration x _{1 of} city gas that may exist in the sample gas and the propane concentration y ₁ Calculated based on the ratio c between the ethane concentration x ₁ and the methane concentration z ₁ in the city gas, and the ratio b between the ethane concentration x ₂ and the propane concentration y _{2 of} LPG that may be present in the sample gas, The concentration of each gas in the sample gas is determined by the ethane concentration x ₁ and propane concentration y ₁ of the city gas in the sample gas, the methane concentration z ₁ , and the ethane concentration x ₂ and propane concentration y ₂ of the LPG in the sample gas. Measuring method of gas concentration to detect. The ethane concentration x of the measurement value is x = x ₁ + x ₂ , and the propane concentration y of the measurement value is y = y ₁ + y ₂ , from x ₁ / y ₁ = a, x ₂ / y ₂ = b ,
_{x 1 = a (by-x} ) / (b-a)
_{x 2 = b (x-ay} ) / (b-a)
_{y 1 = (by-x)} / (b-a)
y ₂ = (x−ay) / (b−a)
The gas concentration measuring method according to claim 3, which is obtained as follows. The methane concentration z in the sample gas is measured, and the naturally occurring methane that can be present in the sample gas based on the ratio c of the ethane concentration x ₁ and the methane concentration z ₁ of the city gas that may be present in the sample gas the concentration Cm, Cm = z-x obtained by ₁ / c claim 3 or 4 measuring method of gas concentration according. Based on the ethane concentration x _{2 of} LPG that may be present in the sample gas and the ratio b of the ethane concentration x ₂ and the propane concentration y ₂ , the concentration Cp of LPG in the sample gas is obtained by Cp = y ₂ / β. The method for measuring a gas concentration according to any one of claims 3 to 5. The methane concentration z in the sample gas is measured, and the ratio c between the ethane concentration x ₁ and the methane concentration z ₁ of the city gas that can exist in the sample gas, and the city gas that can exist in the sample gas The density Ct of the city gas in the sample gas is obtained by Ct = x ₁ (1 + 1 / a + 1 / c) / (1-α) based on the ratio α of the miscellaneous gas. The measuring method of the gas concentration as described in 2. A gas type identification device for identifying each gas type of city gas, LPG, and naturally occurring methane in a sample gas,
Separation column for separating gas components of ethane, propane and methane in the sample gas, a concentration detector for detecting concentrations of the ethane, propane and methane gases, a measured value of the ethane concentration, and a propane concentration The sample gas based on the measured value of the gas, the ratio of the ethane concentration of the city gas that may be present in the sample gas and the propane concentration, and the ratio of the ethane concentration of LPG that may be present in the sample gas and the propane concentration An apparatus for measuring a gas concentration comprising ethane concentration and propane concentration of city gas therein, and arithmetic means for obtaining ethane concentration and propane concentration of LPG in the sample gas.

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