JP3138978B2 - Calorimetric method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a calorimetric method for measuring a calorific value by measuring a measurable physical quantity such as thermal conductivity and density of a fuel gas to be measured.

[0002]

2. Description of the Related Art In processes requiring high heat, liquefied petroleum gas (LPG) having a high calorific value is diluted with air to a predetermined calorific value, and this is used as fuel. Here, when adjusting the amount of heat, while measuring the amount of heat, the amount of air to be diluted is adjusted so that the measurement result becomes a predetermined value (the amount of heat). In addition, city gas is supplied by adjusting natural gas (LNG) to a predetermined calorific value by mixing LPG with natural gas (LNG) as a raw material. Calorimeters are used to measure the calorific value of fuel gas and city gas.The most basic method of measuring the calorific value by burning the gas and the heat generation using the relationship between gas density and calorific value There is a method of measuring the amount. In addition, a method of measuring the heat conductivity to obtain the calorific value of the gas to be measured has been proposed.

A calorimeter for measuring the calorific value by burning this gas completely burns the sample gas in a bomb filled with high-pressure oxygen, and transfers the heat generated at this time to a certain amount of water to burn the gas. The heat of combustion of the sample gas is obtained by measuring the water temperature rise before and after. On the other hand, the calorimetric measurement method based on the gas density method utilizes that the relationship between the calorific value and the gas density can be approximated by a linear expression, obtains the density of the gas to be measured, and prepares a conversion formula or calibration curve prepared in advance. Thus, the calorific value is calculated.

Further, in the calorimetric measurement of the thermal conductivity type, the fact that the relationship between the thermal conductivity and the calorific value of the gas to be measured can be approximated by a linear equation as in the above-mentioned gas density type is used. The heat conductivity of the gas is obtained, and the calorific value is obtained by a conversion formula or a calibration curve prepared in advance. In this method, the value does not change substantially in the pressure range where the thermal conductivity is about the atmosphere. Normally, this measurement is used in a constant temperature bath, so fluctuations in the surrounding environment such as temperature and gas fluctuations And the calorific value of the gas can be measured continuously.

[0005] In addition to the above-mentioned measuring methods, the concentrations of the constituent components of the gas for which the calorific value is determined are measured using a gas chromatograph, and the calorific value is multiplied by each of the measured concentrations to obtain the total calorific value. Is also available. However, the combustion calorimeter has a problem that the response is slow because the gas needs to be burned, and that the influence of a temperature change due to a change in the surrounding environment is large. On the other hand, the method using a gas chromatograph has a problem that the measurement is intermittent, continuous analysis cannot be performed, and the response is slow. For this reason, a gas density type calorimeter or a thermal conductivity type calorimeter, which has a quick response and enables continuous measurement, is usually used.

[0006]

By the way, as described above,
L used for calorific value adjustment in city gas production
PG is basically composed of propane or butane, but may be a mixture thereof. For this reason, the composition differs for each LPG used, and the calorific value differs. On the other hand, in the calorimetric measurement of the gas density type or the thermal conductivity type described above, the relationship between the measurable gas density or the thermal conductivity and the corresponding calorific value (calibration curve) must be prepared in advance. Here, if the composition of the LPG used for obtaining the calibration curve prepared first and the LPG actually used for gas production are different, an error occurs in the measurement result, and accurate measurement cannot be performed. There was a problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to make it possible to accurately measure a calorific value even when source gases having different composition ratios are used. I do.

[0008]

According to the calorimetric method of the present invention, first, the calorific value calculated from the mixing amount when the first component is mixed with the first gas and the first component of the mixing amount are calculated as follows. The first relationship with the physical quantity when mixed is determined. Next, a second relation between a calorific value calculated from a mixing amount when the second component is mixed with the first gas and a physical amount when the second component of the mixing amount is mixed is determined. Then, based on the first and second relationships, a calibration curve when a second gas having a known ratio of the first and second components is mixed with the first gas is calculated. Therefore, only by preparing three types of gases, the relationship between the calorific values of the gases having a plurality of compositions and the measurable physical quantities can be obtained.

[0009]

Embodiments of the present invention will be described below with reference to the drawings. First embodiment. LPG used for calorific value adjustment is mainly composed of propane (C ₃ H ₈ ) and butane (C ₄ H ₁₀ ), and when the ratio C ₃ : C ₄ is different, the calorific value is also different. For example, when this is used as a fuel gas, the amount of heat is adjusted by diluting the LPG having such a configuration with air.

Here, for example, when the calorific value is measured using the thermal conductivity type calorimetric measurement, first, when the LPG (second gas) is composed only of propane (first component). Then, a relation A (approximate expression) between the heat conductivity (physical quantity) and the heat quantity that changes with the quantity of air (first gas) to be mixed is determined. The calorific value is calculated from the concentration of propane. Then, similarly, a relation B (approximate expression) between the thermal conductivity and the heat amount when the LPG (second gas) is composed of only butane (second component) is determined. Relationship A is shown in FIG.
Is represented by y = −ax + b. Further, as shown by a straight line 2 in FIG.
It is represented by x + b.

When the LPG is composed of propane and butane, the relation C (calibration curve) is expressed by y = -a "x + b, and a" is a value between a and a '. Becomes Since the value of a ″ changes in proportion to C ₃ : C ₄ , a ″ = (a−a ′) × {propane concentration /
(Propane concentration + butane concentration)｝ + a ′. Therefore, in calorimetric measurement when diluting and using LPG for which C ₃ : C ₄ is known in advance, a ″ is obtained as described above, and the relationship C (y = −a ″) is obtained.
The calorific value may be obtained from the measured thermal conductivity using the calibration curve 3 (x + b) (FIG. 1). By doing so, even if C ₃ : C ₄ is different, if it is known, the calorific value can be measured without error.

In the above, the case of using the calorimetric measurement of the thermal conductivity type has been described, but the present invention is not limited to this. The same applies to the case of using the gas density calorimetry. In this case, the relationship between the measured gas density and the calorific value may be replaced with the above-described relationship between the thermal conductivity and the calorific value. In other words, the same applies to the case where the relationship between the physical quantity and the calorie of the calorie measurement target, which is approximately related to the calorie by a linear expression, is replaced with the above-described relationship between the thermal conductivity and the calorific value. Further, the association may be made not only by a linear expression but also by using a polynomial expression.

Second Embodiment In the case of city gas using LNG as a raw material, as described above, these raw materials are imported from a plurality of countries of origin so that the supply of the raw gas does not stop. I use it. Then, the gases from the various countries of origin are mixed to form LNG (first gas) as a raw material, and LPG (second gas) for calorific value adjustment is mixed therewith so as to be supplied as city gas. I have.

Since LNG contains methane as a main component, for example, the relationship between the thermal conductivity and the calorific value is close to that of methane, but other subcomponents (ethane, propane, butane, etc.)
Are not exactly the same. And the same L
Even in the case of NG, the composition ratios of the components are different due to different production areas, and the relationship between the thermal conductivity and the calorific value is different.

Therefore, when using the calorimetric measurement of the thermal conductivity type or the density type, ideally, in the LNG of each production area, for example, the relation between the thermal conductivity and the heat value when propane is mixed is calculated. It may be checked and used as a calibration curve. Here, for example, in the production of a calorimeter of the thermal conductivity type, since the characteristics differ for each manufactured calorimeter, a calibration curve is prepared for each manufactured calorimeter.

This calibration curve is prepared by preparing a standard gas having a composition close to LNG, in which the proportions of methane as the main component and subcomponents such as ethane, propane and butane are known. Propane is mixed, and the relationship between the mixing amount and the measurement result of the thermal conductivity at that time is determined. The calorific value when a standard gas of known composition and propane are mixed with this to change the composition ratio of propane can be calculated. A calibration curve can be created based on the calorie obtained by this calculation and the thermal conductivity obtained as a result of the measurement.

By the way, as mentioned above, the composition ratio of the components of LNG differs depending on the place of production. For example, as described above, in city gas production, these raw materials are imported and used from a plurality of countries of origin so that the supply of LPG and LNG as raw materials does not stop. For this reason, in preparing a calibration curve of a calorimeter of a thermal conductivity type or a density type, it is necessary to prepare a standard gas corresponding to a composition state different for each production area.

[0018] However, it is difficult to prepare a standard gas corresponding to each production area, due to restrictions on the calorimeter production. There is a problem in preparing all of these standard gases for adjusting the meter. For this reason, there is a case where one standard gas having a typical component ratio is prepared, and a calibration curve is created and adjusted using the standard gas. However, this does not allow accurate calorimetric measurement.

The following description is directed to a thermal conductivity calorimeter used for calorimetric measurement when producing city gas from natural gas as a raw material, and propane is used for calorific value adjustment in gas production. By the way, L of the calorimetric object
An ideal calibration curve can be created by mixing NG with propane, setting the mixing amount to 0 to 100%, and using the calorimetric result at that time. Therefore, when preparing a calibration curve obtained by linearly approximating the relationship between the heat conductivity and the calorific value for each LNG producing country, the linear equation y = −ax + b of the calorie y indicating the calibration curve and the thermal conductivity x is expressed as a. b may be obtained for each country of origin. However, this has many problems, such as the need to prepare a standard gas corresponding to each country of origin, as described above.

Here, since the calorific value of propane 100% is about 24,000 kcal, the calibration curve is always 24000 kcal at the same thermal conductivity regardless of the producing country of LNG. In other words, no matter which country of origin LNG is used to create a calibration curve, they intersect at 24000 Kcal. The range of the actual measurement is 1100
It is around 0 kcal. Therefore, in the range actually measured, even if the producing countries are different and the composition ratios are different, the slopes of the approximate straight lines indicating the relationship between the thermal conductivity and the amount of heat are considered to be almost the same.

Therefore, in the calorific value measurement in the city gas production, the above-mentioned facts are utilized and the L value used for calorific value adjustment
A calibration curve corresponding to each LNG producing country is prepared by changing the value of b of the calibration curve y = −a ″ x + b obtained by C ₃ : C ₄ of PG for each LNG producing country. Another value of “b” is a calorific value adjustment point of each calibration curve ideally obtained once for each country of origin, for example, 11000.
What is necessary is just to obtain from the difference of the thermal conductivity in kcal.

By this means, when preparing a calibration curve for each calorimeter produced in the calorimeter production and for periodic adjustment of the calibration curve, etc., pure gas of methane, propane and butane can be prepared without preparing a plurality of standard gases. It will be good if you prepare. That is, the C ₁ -C ₃ relationship is obtained by mixing methane with propane, the C ₁ -C ₄ relationship is obtained by mixing methane with butane, and the C _{3 of} LPG used from these two relationships is obtained. :. the information C _4, to obtain a calibration curve y = -a "x + b to be the standard and this calibration curve y =
If "b" of -a "x + b is set for each LNG calculation country, a desired calibration curve is obtained.

[0023]

As described above, according to the present invention, the amount of heat calculated from the mixing amount when the first component is mixed with the first gas and the amount of the first component at this mixing amount are mixed. The first relationship between the measured first gas and the physical quantity that can be measured, the amount of heat calculated from the amount of mixture when the second component is mixed with the first gas, and the second component when this amount of mixture is used Calculating a calibration curve when a second gas having a known ratio between the first and second components is mixed with the first gas, based on a second relationship between the first gas and the measurable physical quantity of the mixed first gas. I made it. For this reason, only by preparing three types of gases, the relationship between the calorific value of the gas having a plurality of compositions and the measurable physical quantity can be obtained.
Even when the source gases having different composition ratios are used, there is an effect that the calorific value can be accurately measured.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a method for creating a calibration curve according to a first embodiment of the present invention.

[Explanation of symbols]

 1, 2, ... straight line, 3 ... calibration curve.

Claims (2)

(57) [Claims] 1. A fuel gas whose calorific value is adjusted by mixing a second gas composed of a first component and a second component with a first gas, and a measurable physical quantity of the fuel gas is measured. In a calorimetric method for determining the calorific value of the fuel gas by a calibration curve indicating the relationship between the calorific value of the fuel gas and the physical quantity, the calorimetric method includes the steps of: mixing the first component with the first gas; Calculated from the first relationship between the calorific value to be calculated, the physical quantity when the first component of the mixed amount is mixed, and the mixed amount when the second component is mixed with the first gas. The second gas having a known ratio between the first and second components is formed by the second relationship between the amount of heat to be performed and the physical amount when the second component of the mixed amount is mixed. Calculating the calibration curve when mixed with the first gas. Calorimetric method. 2. The calorimetric method according to claim 1, wherein the first relation is obtained from a main component of the first gas and the first component, and the second relation is the first gas. A calorimetric method, wherein the calorimetric method is obtained from a main component of the first gas and the second component, and finely adjusts the calibration curve according to a state of a subcomponent of the first gas.