JP5646856B2 - Calorimeter and calorimeter measuring method - Google Patents

Description

  The present invention relates to a calorimeter and a calorimeter measuring method.

  Conventionally, as a calorimeter for measuring the calorific value of a gas, a calorimeter having a configuration for obtaining a calorific value based on the thermal conductivity of a calorimetric gas (hereinafter also referred to as “measured gas”), A structure that obtains the amount of heat based on the density or a structure that obtains the amount of heat based on the refractive index of the gas to be measured is used (for example, see Patent Documents 1 to 3).

  In the calorimeter with such a configuration, the amount of heat of the paraffinic hydrocarbon gas as the gas to be measured is proportional to the refractive index and density, and is also inversely proportional to the thermal conductivity. The amount of heat is measured, and the amount of heat is calculated from a measured value of the thermal conductivity, density, or refractive index of the gas to be measured by a specific formula, specifically, a measurement for calculating the amount of heat once. It is obtained by obtaining a value and performing an operation according to a specific calculation formula based on the measured value.

Japanese Patent Application No. 2-257046 Japanese Patent Application No. 10-38827 Japanese Patent Application No. 8-320300

  The present invention was made as a result of repeated research conducted by the inventors on a method for measuring the calorific value of paraffinic hydrocarbon gas, hydrogen gas, and a mixed gas thereof. The purpose of the present invention is paraffinic hydrocarbon gas. Another object of the present invention is to provide a novel calorimeter and calorimeter method for measuring the calorific value of hydrogen gas and a gas selected from these mixed gases.

The calorimeter of the present invention uses a paraffinic hydrocarbon gas, hydrogen gas or a mixed gas thereof as a calorimetric gas,
A pipe having a tapered internal space that extends in the vertical direction, has a calorimeter gas inlet at the lower end, and has a calorimeter gas outlet at the upper end, and has a cross-sectional area that increases upward. A float calorimeter having a structure in which a float is housed in an internal space of the body so as to be movable up and down, and a supply port for a calorimetric gas to be communicated with an inflow port of a tubular body in the float calorimeter. By setting the cross-sectional area of the mouth to a constant area and setting the supply pressure of the calorimetric gas at this supply port to a known pressure, the calorimetric gas is controlled under specific supply conditions for a float calorimeter. And a supply mechanism for supplying,
The amount of heat per unit volume of the calorimetric gas acquired in advance, and the float that moves up and down by supplying the calorimetric gas under specific supply conditions and flowing through the internal space of the tube in the float calorimeter Based on the correlation with the vertical position of the pipe body, the float position in the float calorimeter measured when the calorimetric gas is supplied under a specific supply condition from the supply mechanism is checked against the correlation. By doing so, the calorific value per unit volume of the calorimetric gas is obtained.

In the calorimeter of the present invention, the tube constituting the float calorimeter is configured such that at least a portion corresponding to the range in which the float can move up and down can be visually observed. It is preferable that a scale display indicating the amount of heat per unit volume is provided in a portion corresponding to the up and down movable range.

The calorimetric method of the present invention is a calorimetric method for measuring the calorie per unit volume of gas,
Use a paraffinic hydrocarbon gas, hydrogen gas, or a mixture of these as the gas for calorimetric measurement,
A pipe having a tapered internal space that extends in the vertical direction, has a calorimeter gas inlet at the lower end, and has a calorimeter gas outlet at the upper end, and has a cross-sectional area that increases upward. Supply a calorimeter gas to a float calorimeter with a float accommodated in the internal space of the body from the calorific gas supply port communicating with the inlet of the tube of the float calorimeter Then, by flowing into the internal space of the pipe body from the inlet, the vertical position of the float pipe body that moves up and down as the calorimetric gas flows through the internal space, the cross-sectional area of the supply port, and this supply Based on the pressure of the calorimetric gas at the mouth,
The heat quantity per unit volume of the calorimetric gas to be obtained in advance and the calorific gas to be measured are supplied under specific supply conditions in which the supply pressure at the supply port having a constant cross-sectional area is a known pressure. The heat quantity per unit volume of the calorific value measurement target gas is obtained from the correlation with the vertical position of the float tube that moves up and down by flowing through the internal space.

  In the calorific value measuring method of the present invention, the calorimetric gas is measured according to a specific supply condition in which the supply pressure of the calorimetric gas at the supply port having a constant cross-sectional area is a known pressure with respect to the float calorimeter. It is preferable to supply.

  According to the calorimeter of the present invention, a specific gas is used as a calorimetric gas, and the internal space is moved up and down in a tubular body having a tapered internal space in which an inflow port and an outflow port of the calorimetric gas are formed. A float-type calorimeter configured to accommodate a float so as to be movable, and a supply mechanism capable of supplying a calorific value measurement target gas to the float-type calorimeter under a specific controlled supply condition. Therefore, there is a correlation between the calorific value of the calorimetric gas and the vertical position of the float in the float calorimeter tube when the calorific gas is supplied and circulated under specific supply conditions. By utilizing, the calorie | heat_amount of calorie | heat amount measuring object gas can be calculated | required by reading the position of the float in a float type calorimeter.

  Further, in the calorimeter of the present invention, by providing a scale display indicating the calorific value of the calorimetric gas on the tube constituting the float calorimeter, the calorific value of the calorimetric gas is moved up and down in the pipe. It can be directly confirmed visually from the position of the float to be performed.

  According to the calorimetric method of the present invention, the float calorimeter has a specific gas as a calorimetric gas, and a float calorimeter including a tube and a float through which the calorimetric gas is circulated. By supplying the calorimetric gas from the supply port communicating with the inlet of the tube body, the calorific value of the calorimetric gas and the supply pressure at the supply port having a constant cross-sectional area are obtained in advance. Float calorimeter using the correlation with the vertical position of the float that goes up and down by flowing through the internal space of the tube body in the float calorimeter, which is supplied under a specific supply condition with a known pressure The calorific value of the calorific value measurement target gas can be determined based on the position of the float, the cross-sectional area of the supply port, and the pressure of the calorimetry target gas supplied from the supply port.

  In the calorimetric method of the present invention, the float calorimeter has a specific cross-sectional area with a constant cross-sectional area of the supply port and a specific pressure in which the supply pressure of the gas to be measured at the supply port is a known pressure. By supplying the calorimeter gas according to the supply conditions, the calorie of the calorimeter gas can be obtained directly from the position of the float.

It is explanatory drawing which shows the outline | summary of an example of a structure of the calorific value measuring apparatus of this invention. It is explanatory drawing which shows an example of a structure of the float type calorimeter which comprises the calorimeter of FIG. 1, (A) is sectional drawing for description, (A) is a bottom view for description. It is a graph which shows the relationship between the position of the float ball | bowl which concerns on sample gas, and the calorie | heat amount obtained in Experimental example 1-Experimental example 3. FIG.

  Hereinafter, embodiments of the present invention will be described in detail.

FIG. 1 is an explanatory view showing an outline of an example of the configuration of the calorimeter of the present invention, and FIG. 2 is an explanatory sectional view showing an example of the configuration of a float calorimeter constituting the calorimeter of FIG. It is.
The calorimeter of the present invention uses a paraffinic hydrocarbon gas, hydrogen gas, or a mixed gas thereof as a calorimetric gas (hereinafter also referred to as “gas to be measured”). The float calorimeter 10 has a configuration including a supply mechanism for supplying a measurement gas under specific supply conditions.

The float calorimeter 10 constituting the calorimeter of the present invention is provided with a substantially cylindrical tubular body 12 having transparency and extending in the vertical direction. The tubular body 12 is provided at the upper end and the lower end, respectively. The lower end has a gas inlet 13A for allowing the gas to be measured to flow in, and the upper end has a gas outlet 13B for allowing the gas to be measured to flow out. The internal space 15 is formed. The inner space 15 of the tubular body 12 accommodates a true spherical float (hereinafter also referred to as “float ball”) 18 that can move up and down in the inner space 15.
Further, a lower limit stopper 17A for defining a lower limit position and an upper limit stopper 17B for defining an upper limit position in the internal space 15 of the float ball 18 are provided in the tube body 12.
In the example of this figure, the lower limit stopper 17A and the upper limit stopper 17B are each formed of, for example, a flat plate made of polytetrafluoroethylene. The lower limit stopper 17A and the upper limit stopper 17B are fixed in a state where the lower limit stopper 17A is embedded in the inner peripheral wall on the lower bottom surface side of the internal space 15 in which the gas inlet 13A is located. On the other hand, the upper limit stopper 17B is fixed in a state where the side end portion is embedded in the inner peripheral wall on the top head surface side of the internal space 15 where the gas outlet 13B is located.

The tube body 12 is made of, for example, heat resistant glass.
Examples of the heat resistant glass include Pyrex (registered trademark) glass.

  The float ball 18 is made of, for example, black glass and has a weight of, for example, 37.5 mg.

Here, an example of the dimension of the structural member of the float type calorimeter 10 in the example of FIG. 1 is shown below.
The tubular body 12 has a tapered external shape, and thereby the internal space is tapered. The tubular body 12 has a total length of, for example, 64.00 mm, and an outer diameter at the lower end. For example, 9.35 mm and the outer diameter of the upper end is, for example, 9.55 mm.
In the float ball 18, the spherical diameter is, for example, φ3 mm.
In the lower limit stopper 17A, the total length is, for example, 8.5 mm.
The total length of the upper limit stopper 17B is, for example, 5.5 mm.

The float calorimeter 10 has a gas inlet 13 </ b> A of the tubular body 12 constituting the float calorimeter 10 communicated with a gas supply port 23 having a specific cross-sectional area via a gas supply path 21. A supply pressure adjusting means 22 for controlling the supply pressure of the gas to be measured at the gas supply port 23 is provided on the gas supply path 21 upstream of the gas supply port 23. The gas supply port 23 and the supply pressure adjusting means 22 constitute a supply mechanism.
This supply mechanism adjusts the cross-sectional area of the gas supply port 23 and the supply pressure of the gas to be measured at the gas supply port 23, thereby allowing the gas to be measured to be supplied to the float calorimeter 10 under controlled supply conditions. The amount of gas to be measured that is supplied, that is, supplied from the gas supply port 23 to the float calorimeter 10, specifically, the amount of gas to be measured that is supplied from the gas supply port 23 within a certain period of time. Thus, the supply condition of the measurement gas to the float calorimeter 10 is controlled.

  The gas supply port 23 only needs to have a cross-sectional area (opening area) having a specific size, and for example, a variable orifice such as a needle valve or a fixed orifice can be used.

  For example, a pressure reducing valve can be used as the supply pressure adjusting means 22.

In the float calorimeter 10, the tube body 12 is provided with a scale display indicating the amount of heat of the gas to be measured at a portion corresponding to the range in which the float ball 18 can move up and down.
The scale display indicating the amount of heat indicates that the gas to be measured is supplied from the supply mechanism to the float calorimeter 10 in a specific supply condition, specifically, the cross-sectional area of the gas supply port 23 is a constant area. At the same time, the supply pressure of the gas to be measured at the gas supply port 23 is a known pressure, and the float ball in the tube 12 when the gas to be measured is circulated through the internal space 15 of the tube 12 in the float calorimeter 10. 18 is provided based on the correlation between the vertical position of 18 and the amount of heat.

The correlation between the vertical position of the float ball 18 in the tubular body 12 and the amount of heat indicates that the float ball in a state in which the gas to be measured is circulated in the internal space 15 of the tubular body 12 in the float calorimeter 10 under specific supply conditions. 18 for measuring the position and the amount of heat, that is, for each type of gas to be measured, the gas to be measured is supplied from the supply mechanism to the supply pressure at the gas supply port 23 having a specific cross-sectional area (a constant cross-sectional area). Based on the vertical position of the float ball 18 measured under this specific supply condition and the amount of heat measured by a known calorimeter, supplied at a specific supply condition with a specific pressure (known pressure) To be acquired.
Specifically, as shown in an experimental example to be described later, for each of a plurality of types of gas to be measured having different composition ratios, the gas to be measured is fixed with respect to a float calorimeter having a tube body and a float. From the gas supply port having a cross-sectional area, the supply pressure at the gas supply port is supplied at a known pressure (for example, 0.05 MPa) and is introduced from the gas inlet of the tube, whereby the gas to be measured is circulated. In addition to measuring the vertical position of the float in the tube that is in a state of being measured, the calorific value of the gas to be measured is measured by a known calorimeter, and the measurement value of the float position and the calorific value obtained in this way are measured. The relationship with the value can be obtained, for example, by graphing.

In the calorimeter of the present invention having such a configuration, the gas to be measured is supplied from the supply mechanism to the float calorimeter 10, that is, the gas to be measured is supplied from the gas supply port 23 via the gas supply path 21. When the gas to be measured flows in from the gas inlet 13A of the tube body 12 by being supplied, the float ball 18 is pushed up by the gas to be measured, and the float ball 18 is located above and below the float ball 18 in the tube body 12. Based on the correlation between the position of the direction and the amount of heat, as the amount of heat of the gas to be measured decreases, it moves to the upper end side of the tube body 12 of the float calorimeter 10, that is, rises. As it becomes larger, it moves to the lower end side of the tubular body 12, that is, descends.
Here, in the float calorimeter 10, as shown in FIG. 3, the float ball 18 has a vertical position and a heat amount of the float ball 18 in the internal space 15 of the tube body 12 as the heat amount increases. Therefore, when the amount of heat of the gas to be measured is small, when the amount of heat of the gas to be measured is below a certain level, the raised float ball 18 is In contact with the upper limit stopper 17B disposed at the upper end, on the other hand, when the amount of heat of the gas to be measured is large, when the amount of heat of the gas to be measured exceeds a certain level, the lowered float ball 18 is disposed at the lower end of the tube body 12. The lower limit stopper 17A thus made is brought into contact with.

Thus, in the float calorimeter 10, the supply condition of the gas to be measured supplied from the supply mechanism to the float calorimeter 10 is provided in the tube 12 of the float calorimeter 10. By setting the specific supply condition that matches the supply condition for the scale display indicating the amount of heat (the supply condition when the correlation related to the scale display is acquired), the float calorimeter 10 uses the calorimeter 10 according to the present invention. Based on the position of the float ball 18 in the vertical direction to be measured, the amount of heat is directly obtained from the position of the float ball 18 measured by the scale display indicating the amount of heat provided in the tube body 12.
That is, based on the correlation between the position in the vertical direction of the float ball 18 in the tubular body 12 and the amount of heat when the gas to be measured is circulated in the internal space 15 of the tubular body 12 under specific supply conditions, which is acquired in advance. Then, the vertical direction position of the float ball 18 in the tubular body 12 measured by the float calorimeter 10 is collated with the correlation by the scale display of the heat amount provided in the tubular body 12, thereby measuring the gas to be measured. The amount of heat is required.

The calorimeter of the present invention as described above uses a gas containing at least paraffinic hydrocarbon gas or hydrogen gas as a gas to be measured.
Specifically, the gas to be measured is a gas made of only paraffinic hydrocarbon gas, a gas made of only hydrogen gas, or a mixed gas of paraffinic hydrocarbon gas and hydrogen gas.

  Preferable specific examples of the gas to be measured include city gas that is a mixed gas of paraffinic hydrogen gas (methane gas, ethane gas, ethylene gas, propane gas, propylene gas, butane gas, etc.) and hydrogen gas.

According to the calorimeter as described above, the gas to be measured that is to be introduced from the gas inlet 13A of the pipe body 12 constituting the float calorimeter 10 is supplied from the supply mechanism to the gas having a constant cross-sectional area. When the supply pressure is controlled so that the supply pressure at the port 23 becomes a known pressure, that is, the gas to be measured is supplied to the float calorimeter 10 under specific supply conditions, and the tube body 12 is supplied. The correlation between the vertical position of the float ball 18 and the amount of heat in the tube 12 when the gas to be measured is circulated in the internal space 15 is that the position of the float ball moves downward as the amount of heat increases. By making use of what is included, the amount of heat of the gas to be measured is confirmed visually by checking the vertical position of the float ball 18 in the pipe body 12. It can be obtained directly by reading the scale display that indicates the amount of heat that is.
In this calorimeter, for example, by using a camera or the like, the heat amount of the gas to be measured is confirmed while observing the position of the float ball 18 in the float calorimeter 10, or the heat amount of the gas to be measured is recorded. Can do.

Although the calorimeter and the calorimeter method of the present invention have been specifically described above, the present invention is not limited to the above examples, and various modifications can be added.
For example, the calorimeter is not limited to one having transparency, as long as the tube constituting the float calorimeter can visually confirm the position of the float, and has translucency. It may also be configured to be transparent or translucent, for example, so that at least a portion corresponding to the floatable range of the float can be visually observed.
In addition, the calorimeter does not have to be provided with a scale display indicating the amount of heat on the tube constituting the float calorimeter, and measures the vertical position of the float in the tube, and the measured value at that position is measured. The amount of heat may be obtained by collating with the correlation between the float position and the amount of heat acquired in advance.

  Further, the calorimetric method is not limited to being performed by the calorimeter of the present invention, and the correlation between the calorific value of the calorimetric gas and the vertical position of the float in the float calorimeter acquired in advance. It is only necessary to obtain the amount of heat by using the relationship. For example, even if the supply pressure of the gas to be measured at the gas supply port is not a known pressure, the pressure at the gas supply port (the pressure upstream of the gas supply port) and The pressure at the gas inlet of the tube (the pressure at the downstream side of the gas supply port) is measured, and the pressure difference is proportional to the supply amount of the gas to be measured supplied from the gas supply port. Based on this, the float position under specific supply conditions (conditions where the supply pressure at the gas supply port is a known pressure) is converted, and the amount of heat is determined from the converted float position. It may be.

Hereinafter, experimental examples of the present invention will be described.
Here, Experimental Example 1 and Experimental Example 2 are experimental examples performed in order to obtain a correlation between the vertical position of the float and the amount of heat in a float calorimeter composed of a tubular body and a float. In addition, Experimental Example 3 is an experimental example that was performed to confirm the operational effects of the present invention.

[Experimental Example 1]
A tube made of Pyrex (registered trademark) glass having the same configuration as the float calorimeter of FIG. 2 and having the dimensions shown below, and a float ball made of black glass having a spherical diameter of 3 mm and a weight of 35.7 mg, And a float type calorimeter provided with a scale display of the flow rate for air at 1 atm (atmospheric pressure) and 20 ° C. in the range of 50 to 500 [mL / min].
In this float calorimeter, the tube has a tapered external shape, whereby the internal space is tapered, the total length is 64.00 mm, the outer diameter of the lower end is 9.35 mm, and the upper end is The outer diameter is 9.55 mm, the lower limit stopper has a total length of 8.5 mm, and the upper limit stopper has a total length of 5.5 mm.

Using the prepared float calorimeter, propane gas and hydrogen gas are contained, and a mixed gas of a plurality of types of propane gas and hydrogen gas having different content ratios is used as a sample gas. A needle valve “model: 2412-T-SS-1 / 4- # 5” (manufactured by Cofrock) is connected to the gas inlet of the tube constituting the float calorimeter through a gas supply path, and the opening The area (cross-sectional area) is set so that the flow rate when methane gas is supplied at a pressure of 0.05 MPa is 280 mL / min, and a pressure reducing valve “model: RD1201A412201” (Henmi) is provided upstream of the needle valve. By this, with respect to the float calorimeter, the pressure at the gas supply port consisting of the needle valve is 0.05 MPa. The sample gas is allowed to flow into the internal space of the tube in the float calorimeter under the supply conditions, and the float ball position is measured by a scale display indicating the flow rate provided in the tube, and at the downstream side of the float calorimeter The calorific value was measured with a refractive index calorimeter “FI-800” (RIKEN KEIKI Co., Ltd.) provided in the instrument. Based on the position of the float ball and the amount of heat obtained by the refractive index calorimeter (hereinafter also referred to as “heat value true value”), the relationship between the position of the float ball and the value of heat value was confirmed. The results are shown in FIG.
In addition, the scale display which shows the flow volume provided in the pipe body is attached | subjected so that a numerical value may become large as it goes upwards similarly to the scale of the flow volume provided to the well-known float type flow meter.
In FIG. 3, the results according to Experimental Example 1 are plotted with “■” (square).

[Experimental example 2]
In Experimental Example 1, the sample gas contains isobutane and hydrogen gas, and floats in the same manner as in Experimental Example 1 except that a mixed gas of a plurality of types of isobutane and hydrogen gas having different contents is used. The relationship between the ball position and the true value of heat was confirmed. The results are shown in FIG.
In FIG. 3, the results according to Experimental Example 2 are plotted with “▲” (triangle).

  From the results of Experimental Example 1 and Experimental Example 2 above, in the mixed gas of paraffinic hydrocarbon gas and hydrogen gas, the amount of heat increases between the vertical position of the float ball in the tube and the amount of heat. It has become clear that there is a correlation in which the position of the float ball moves downward in accordance with the above, and this correlation is acquired by the method according to the first and second embodiments.

[Experimental Example 3]
In Experimental Example 1, as a sample gas, hydrogen gas (H ₂ ; molecular weight 2), methane gas (CH ₄ ; molecular weight 16), ethane gas (C ₂ H ₆ ; molecular weight 28), propane gas (C ₃ H ₈ ; molecular weight 44) Float balls in the same manner as in Experimental Example 1 except that nitrogen gas (N ₂ ; molecular weight 28), carbon dioxide gas (CO ₂ ; molecular weight 44) and sulfur hexafluoride gas (SF ₆ ; molecular weight 146) were used. The relationship between the position of and the true value of heat quantity was confirmed. The results are shown in FIG.
In FIG. 3, the results according to Experimental Example 3 are plotted with “♦” (diamond angle), and both the chemical symbol and the molecular weight are shown for each plot.

  From the results of Experimental Example 3 above, hydrogen gas and paraffinic hydrocarbon gas (methane gas, ethane gas, and propane gas) have a calorific value depending on the position of the float ball, similar to the mixed gas of paraffinic hydrocarbon gas and hydrogen gas. It became clear that it could be measured.

DESCRIPTION OF SYMBOLS 10 Float type calorimeter 12 Tube 13A Gas inlet 13B Gas outlet 15 Internal space 17A Lower limit stopper 17B Upper limit stopper 18 Float ball 21 Gas supply path 22 Supply pressure adjusting means 23 Gas supply port

Claims (4)

Use a paraffinic hydrocarbon gas, hydrogen gas, or a mixture of these as the gas for calorimetric measurement,
A pipe having a tapered internal space that extends in the vertical direction, has a calorimeter gas inlet at the lower end, and has a calorimeter gas outlet at the upper end, and has a cross-sectional area that increases upward. A float calorimeter having a structure in which a float is housed in an internal space of the body so as to be movable up and down, and a supply port for a calorimetric gas to be communicated with an inflow port of a tubular body in the float calorimeter. By setting the cross-sectional area of the mouth to a constant area and setting the supply pressure of the calorimetric gas at this supply port to a known pressure, the calorimetric gas is controlled under specific supply conditions for a float calorimeter. And a supply mechanism for supplying,
The amount of heat per unit volume of the calorimetric gas acquired in advance, and the float that moves up and down by supplying the calorimetric gas under specific supply conditions and flowing through the internal space of the tube in the float calorimeter Based on the correlation with the vertical position of the pipe body, the float position in the float calorimeter measured when the calorimetric gas is supplied under a specific supply condition from the supply mechanism is checked against the correlation. By doing so, the calorie | heat amount measuring apparatus characterized by the calorie | heat amount per unit volume of calorie-measurement object gas being calculated | required. The tube constituting the float calorimeter is configured such that at least a part corresponding to the range in which the float can be moved up and down is visible, and a part corresponding to the range in which the float can be moved up and down is provided. 2. The calorimeter according to claim 1, further comprising a scale display showing a calorie per unit volume . A calorimetric method for measuring the amount of heat per unit volume of gas,
Use a paraffinic hydrocarbon gas, hydrogen gas, or a mixture of these as the gas for calorimetric measurement,
A pipe having a tapered internal space that extends in the vertical direction, has a calorimeter gas inlet at the lower end, and has a calorimeter gas outlet at the upper end, and has a cross-sectional area that increases upward. Supply a calorimeter gas to a float calorimeter with a float accommodated in the internal space of the body from the calorific gas supply port communicating with the inlet of the tube of the float calorimeter Then, by flowing into the internal space of the pipe body from the inlet, the vertical position of the float pipe body that moves up and down as the calorimetric gas flows through the internal space, the cross-sectional area of the supply port, and this supply Based on the pressure of the calorimetric gas at the mouth,
The heat quantity per unit volume of the calorimetric gas to be obtained in advance and the calorific gas to be measured are supplied under specific supply conditions in which the supply pressure at the supply port having a constant cross-sectional area is a known pressure. A calorific value measuring method characterized in that a calorific value per unit volume of a calorimetric gas is obtained from a correlation with a vertical position of a float tube that moves up and down by flowing through an internal space.   The calorimetric gas is supplied to the float calorimeter according to a specific supply condition in which a supply pressure of the calorimetric gas at a supply port having a constant cross-sectional area is a known pressure. 3. A calorimetric method according to 3.

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