RU2590981C1 - Method of studying sorption properties of coals - Google Patents

Abstract

FIELD: gas industry.

SUBSTANCE: invention relates to determination of gas retention capacity of coal while forecasting of gas content inside coal beds. Method of studying sorption properties of coals is implemented as follows. Temperature required for analysis is determined following with pumping a measured gas volume under pressure of 1 MPa with further increase of pressure with interval of 1 MPa. Then the volume of absorbed gas is determined by the measured volumes at each pressure value and gas retention capacity of coal is calculated per ton and dry ashless mass with due allowance for moisture and ash content. Then obtained data are used to construct a linear function with indication of formula for both curves. Coefficients are determined from the formula for calculation of Langmuir volume and pressure. Obtained values are used in adsorption equation to determine gas retention capacity. Diagram of measured and calculated values of gas retention capacity as per pressure values is made.

EFFECT: possibility of simultaneous product investigations for determining gas retention properties of coals taken from wells with different formation temperature.

1 cl, 3 tbl, 4 dwg

Description

The invention relates to methods for determining the sorption gas intensity of coals in predicting the gas content of coal seams, calculating the expected gas production in mine workings, methane production volumes from commercial methane production from wells drilled from the surface, and estimating methane reserves in coal deposits.

Closest to the technical nature of the claimed invention is a method for determining the methane consumption of coal (USSR author's certificate No. 454445, IPC G01N 1/00, publ. 25.12.74, bull. No. 47), including the saturation of coal with methane to a pressure of about 60-70 atm. After the establishment of sorption equilibrium, separately measured portions of gas are released with fixation of the equilibrium pressure. Subsequent degassing is carried out in such a way that the moisture contained in the coal and passing into steam in the presence of vacuum and elevated temperature is delayed by an absorber that does not absorb methane, before measuring the gas of the extracted coal.

The disadvantage of this method is the inability to simultaneously conduct research at different temperatures.

The technical result of the invention is to increase the accuracy, quality and reduce the time of research, the possibility of simultaneous research of the sorption properties of coals selected from wells with different formation temperatures.

The technical result is achieved by the fact that in the method for studying the sorption properties of coal, including pumping the measured volume of methane, saturation of the coal with methane and subsequent desorption, according to the invention, the temperature necessary for the study is established, the measured volume of methane is pumped under a pressure of 1 MPa with a subsequent increase in pressure with an interval of 1 MPa inclusive to reservoir, after which the volume of methane absorbed is determined by the amount of methane desorbed, taking into account the correction for the ineffective volume, according to rennym volumes of methane adsorbed at each pressure value of gas capacity calculated per ton and dry ash-free basis, taking into account moisture and ash content, then the data obtained, a linear function indicating formulas for both curves

P / V = m × p + b,

where V is the volume of methane, m ³ / t;

P is the absolute pressure, MPa;

m - calculated from a linear equation as a coefficient (P);

b - calculated from a linear equation as a free coefficient;

after which Langmuir volume and Langmuir pressure are calculated using the formulas

V _L = 1 / m,

where V _L is the Langmuir volume, m ³ / t,

P _L = V _L × b,

where P _L - Langmuir pressure, MPa,

the obtained values of the Langmuir volume and Langmuir pressure are used in the adsorption equation to determine the sorption gas intensity

plot the measured and calculated values of the adsorption volume on pressure values.

The invention is illustrated by drawings, where in FIG. 1 shows a setup for studying the sorption properties of coal (front view), and in FIG. 2 - metering unit of the installation for studying the sorption properties of coal, FIG. 3 - sorption isotherm, FIG. 4 is a graph of the measured and calculated values of the adsorption volume on pressure values.

To implement the method, a facility can be used to study the sorption properties of coal (for example, Dmitriev, A. M. Problems of gas content of coal deposits / A. M. Dmitriev, N. N. Kulikova, G. V. Bodnya. - M .: Nedra, 1982. - S. 55-59), including a metal part, designed for a pressure of 15 MPa, and a glass, which serves to measure the volume of methane at pressures of not more than 0.1 MPa.

The following elements belong to the high-pressure part: line 1 with a crane 2 for supplying methane from a transport cylinder to the methane pre-collection line 3. Methane pre-collection line 3 is connected by cranes 4-8 to methane pre-collection tanks 9-13, which are connected to standard pressure gauges 14-18 for pressure up to 16 MPa. Using metal cranes 19-23, the tanks of the preliminary set of methane 9-13 are connected to standard pressure gauges 24-28 at a pressure of 10 MPa, and using cranes 35-39, to sorption ampoules 41-45. Sorption ampoules 41-45 and pre-set methane tanks 9-13 are seamless steel cylinders for operating pressures up to 20 MPa and having a capacity of 400 ml in the first case and 2000 ml each in the second.

On the lines connecting the metal taps 19-23 and the taps 35-39, there are taps 29-33, which connect the sorption ampoules 41-45 to the low pressure line 46. At the other end of the low pressure line, an exemplary vacuum gauge 40 and valve 34 are placed, and through gas reducer low pressure line connected to the glass part of the installation.

The glass part of the installation consists of a drying tank with calcium chloride CaCl ₂ 47, calibrated containers 50 and 51 with valves 52, 53 and a three-way valve 54 connecting the entire system to a vacuum pump or atmosphere. A drying tank with calcium chloride CaCl ₂ 47 is connected by two three-way valves 48 and 49.

Additionally, each sorption ampoule 41-45 is placed in a thermostat with a temperature sensor, and exemplary pressure gauges 14-18, 24-28 on methane pre-collection tanks 9-13 and sorption ampoules 41-45 are connected to the program module.

Before studying the sorption properties of coal, coal samples are divided into two parts (along the section): one is used for qualitative and carbon-petrographic analysis, the second for studying sorption properties.

The moisture content of the investigated coals is determined in accordance with GOST 52917-2008 Methods for the determination of moisture in an analytical sample.

Determine the ash content of coal (GOST 55661-2013 Methods for determining ash content) and the yield of volatile substances (GOST 55660-2013 Methods for determining the yield of volatile substances). This is necessary to process the results of the analysis. The determination of vitrinite reflectivity (GOST 55659-2013 Method for determining reflection indicators) for each sample and petrographic analysis (GOST 55662-2013 Method for determining petrographic composition) are also carried out.

Determine the actual and apparent density according to GOST 2160-92 Solid mineral fuel. Density determination methods.

The second part of the coal is ground and placed in an adsorption vial. Ampoules are weighed before and after filling with coal, thus determining the weight of a sample of coal. The sorption ampoule is installed in a thermostat with a temperature sensor, the measuring system is evacuated, then the required temperature is set. The tests are carried out at two to three different temperatures for each sample.

Fill with methane from the transport tank capacity of the preliminary set of methane 9-13. The pressure in the cylinders should correspond to the pressure that will be pumped into the sorption vial. After filling the tanks of the preliminary set of methane 9-13 with methane, valves 4-8 are shut off. At the stage of sorption of methane with coal, taps 29-33 are closed. In order for methane to enter sorption ampoules 41-45, taps 19-23 are opened. Then, the measured volume of methane is pumped into sorption ampoules 41-45 under a pressure of 1 MPa. Registration of parameter changes is carried out by the software module. It is necessary to observe the change in pressure until an equilibrium state is reached. Data recording must be carried out until the pressure change becomes insignificant, that is, less than 0.1 MPa per hour for this type of study. If then, within 20 hours, the pressure does not change, it is believed that an equilibrium state has been reached. The coal sample is completely saturated with methane at equilibrium pressure.

To measure the volume of adsorbed methane, taps 19-23 are shut off. Open one of the taps 29-33, the tap 34 and the gas reducer so that excessive pressure does not form in the metering unit, which is fraught with destruction of the glass parts and personal injury. Methane is passed through a drying tank 47 and displaces water from calibrated tanks 50, 51. Methane volume must be carefully measured. The procedure is repeated for each pressure value with an interval of 1 MPa inclusive up to reservoir pressure.

The volume of adsorbed methane is determined by the amount of methane desorbed, taking into account the correction for inefficient volume. The free volume of methane in the tubes and sorption ampoule is called the ineffective volume. When changing the amount of the sample or replacing the sorption ampoule itself, the ineffective volume changes, so it must be measured with each study of the adsorption properties. Ineffective volume is determined using helium, since helium adsorption by the adsorbent is negligible. It is necessary to pump helium into space at different pressures at which the tests will be conducted, and measure the volume of helium.

According to the measured volumes of adsorbed methane at each pressure value (recommended values: 1-2-3-4-5-6-7-7 MPa), a table is built. The gas consumption per ton and dry ashless mass (sbm) are calculated taking into account humidity and ash content. The obtained data from the studies were listed in table 1.

Then build a graph of pressure / volume against pressure values for the ratio of pressure / volume per ton and dry ashless mass. A linear function is constructed for both curves with an indication of the formula (Fig. 3).

P / V = m × p + b,

where V is the volume of methane, m ³ / t;

P is the absolute pressure, MPa;

m - calculated from a linear equation as a coefficient (P);

b - calculated from the linear equation as a free coefficient.

In the example above, m = 0.0302; b = 0.0762.

Langmuir volume and Langmuir pressure are calculated by the formulas:

V _L = 1 / m,

where V _L - Langmuir volume, m ³ / t.

P _L = V _L × b,

where P _L - Langmuir pressure, MPa.

The obtained values of the Langmuir volume and Langmuir pressure are used in the adsorption equation to determine the sorption gas intensity.

Adsorption equation:

where V is the volume of methane, m ³ / t;

P is the absolute pressure, MPa;

V _L - Langmuir volume, m ³ / t;

P _L - Langmuir pressure, MPa.

A graph is plotted of the measured and calculated values of the adsorption volume on pressure values (Fig. 4).

After processing the results by a graphical method, it is possible to obtain the value of the sorption gas intensity of coal for any natural temperature and pressure (for a given formation).

Claims (1)

A method for studying the sorption properties of coal, including pumping a measured volume of gas, saturating coal with methane and subsequent desorption, characterized in that the temperature necessary for the study is established, the measured volume of gas is pumped under a pressure of 1 MPa, followed by an increase in pressure with an interval of 1 MPa, inclusive to the formation, after which determines the amount of absorbed gas by the amount of desorbed, taking into account the correction for the ineffective volume, by the measured volumes of adsorbed methane for each At the beginning of the pressure, the gas consumption per ton and dry ashless mass is calculated taking into account humidity and ash content, a linear function is constructed from the data obtained, indicating the formula for both curves

where V is the volume of gas, m ³ / t;
P is the absolute pressure, MPa;
m - calculated from a linear equation as a coefficient (P);
b - calculated from a linear equation as a free coefficient;
then calculate the Langmuir volume and Langmuir pressure according to the formulas:

where V _L - Langmuir volume, m ³ / t,

where P _L - Langmuir pressure, MPa,
the obtained values of the Langmuir volume and Langmuir pressure are used in the adsorption equation to determine the sorption gas intensity

plot the measured and calculated values of the adsorption volume on pressure values.

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