RU2542998C1 - Gas permeability anisotropy laboratory measurement on whole cores - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: method includes core extraction and drying, core analysis by steady-state filtration of gas through it with measurement of coefficients of vertical and horizontal absolute gas permeability and further analysis of the survey results and measurement of absolute gas permeability anisotropy. While determining coefficient of horizontal absolute gas permeability for the core survey is made in six horizontal directions with measurement interval of 30°. Thereafter vertical anisotropy is calculated for six directions as ratio of horizontal absolute gas permeability to vertical one for each direction. Horizontal anisotropy is also calculated as ratio of maximum absolute gas permeability to minimum one on the basis of values determined for six horizontal directions.EFFECT: improved reliability and accuracy for absolute gas permeability anisotropy on whole cores due to increased number of horizontal gas permeability measurement and improved information content of this method.3 cl, 3 dwg, 2 tbl

Description

The invention relates to the field of oil production, in particular to methods for determining the anisotropy of rock permeability under laboratory conditions, and is intended for laboratory determination of the absolute gas permeability coefficient during stationary filtration on core samples with a diameter stored during drilling in the well in parallel and perpendicular bedding directions. When implementing the proposed method, information is obtained on the filtration properties of rocks, characterized by the presence of elements with pronounced texture features (tile, interlayer), the presence of cracks and caverns larger than 2 mm.

Gas permeability anisotropy is one of the key factors in the construction of 3D geological and hydrodynamic models of the reservoir and in the justification of the development of oil or gas deposits. By anisotropy, here we mean the difference in the absolute gas permeability coefficients in different directions (vertical, horizontal). Permeability measurement on core material selected from the reservoir is the only direct way to evaluate its filtration characteristics.

A known method for determining the anisotropy of the pore space and the position of the main axes of the rock permeability tensor on core (RF patent No. 2492447), according to which the core is studied, for this purpose, the core material is extracted and dried, a plate of 3-5 mm thickness is made from it. Then, distilled water is dosed dropwise to the plate center on a fixed plate on a horizontal surface, and the presence of anisotropy and the direction of the principal axes of permeability anisotropy are determined by the shape of the wet spot formed on the plate. The technical result of this known invention is the creation of an express method for establishing lateral anisotropy of the filtration-capacitive properties of porous media and the position of the main axes of the rock permeability tensor on the core.

The disadvantage of this known method is the limited scope, namely only for terrigenous reservoirs, not complicated by cracks and cavities, which reduces its practical value.

Also known is a method for determining anisotropy of formation permeability in laboratory conditions (RF patent No. 2407889) on a core column 1 meter long with a saved diameter. The method includes the subsequent preparation of the columns by drying and / or extraction or without such preparation. To determine the permeability anisotropy of the formation, a special laboratory setup is used.

The technical result of the specified known method is to increase the degree of reliability of the determination. However, this known research method is very difficult to implement in practice. This is explained by the following:

- as a rule, it is not possible to select a core 1 m long, especially with a complex pore space structure, since usually a core column is represented by pieces up to half a meter;

- the high complexity and duration of the process of extracting a core column of these sizes requires too much labor;

- proposed in the known method, core extraction in a Soxhlet device is largely irrational;

- core research with a length of 1 meter makes it difficult to conduct studies of other physical properties of the rock and obtain the main correlation dependencies of the core-core.

Closest to the proposed technical solution by technical nature is a laboratory method for determining the absolute gas permeability anisotropy on a full-size core (Recommended Practice for Core Analysis. API. RP 40, second edition, February 1998), including core extraction and drying, its study by stationary filtration through gas with the determination of the coefficients of vertical and horizontal absolute gas permeability, the subsequent analysis of the results of the study and the determination of anisotropy of absolute gas permeability ty. In this case, horizontal permeability is measured in two directions: one in the direction of the assumed maximum permeability (along the main cracking), and the other at an angle of 90 ° from the maximum. In this method, a direction parallel to the bedding plane is defined as horizontal permeability, perpendicular to the bedding plane — vertical permeability. However, this method is not without drawbacks, namely:

- the value of the assumed maximum horizontal filtration in the rock may not correspond to the chosen direction, thereby it can be mistakenly assumed that in case of equality of the obtained values from the results of two measurements, the horizontal permeability is isotropic. As a result of this, an error may arise in the calculation of the anisotropy in the future.

- it is difficult to identify the minimum and maximum values of horizontal permeability, due to insufficient information about the distribution of the filtration flow in the sample when performing only two measurements.

The technical result achieved by the proposed method is to increase the reliability and accuracy of determining the anisotropy of absolute gas permeability on a full-sized core by increasing the number of measurements of horizontal gas permeability, and therefore, increasing the information content of this method.

The indicated technical result is achieved by the proposed method for laboratory determination of absolute gas permeability anisotropy on a full-sized core, including core extraction and drying, its study by stationary gas filtration through it with determination of vertical and horizontal absolute gas permeability coefficients, subsequent analysis of the research results and determination of absolute gas permeability anisotropy, while new is that when determining the coefficient horizon the total absolute gas permeability of the core is carried out in six horizontal directions with a measurement step of 30 °, after which vertical anisotropy in six directions is calculated as the ratio of the horizontal absolute gas permeability in each direction to the vertical; horizontal anisotropy is also calculated as the ratio of the maximum absolute gas permeability to the minimum, determined from six horizontal directions.

When determining the coefficient of vertical absolute gas permeability of the core, the gas is filtered through it in the direction perpendicular to the bedding.

When determining the coefficient of horizontal absolute gas permeability of the core, the gas is filtered through it in a direction parallel to the bedding.

Consider the distinguishing features of the invention. New in the proposed method is the following:

- determination of the coefficient of horizontal absolute gas permeability of the core study is carried out in six horizontal directions with a measurement step of 30 °,

- the absolute gas permeability anisotropy in this case is calculated both between vertical and any horizontal directions - vertical anisotropy, and between the maximum and minimum horizontal directions - horizontal anisotropy.

When determining the coefficient of vertical absolute gas permeability of the core, the gas is filtered through it in the direction perpendicular to the bedding. When determining the coefficient of horizontal absolute gas permeability of the core, the gas is filtered through it in directions parallel to the bedding.

The achievement of the specified technical result is ensured by the following.

Due to the fact that the core is pre-extracted and dried, the absolute gas permeability of the rock is determined without the presence of hydrocarbons and aqueous solutions in the pore space.

A core sample prepared in this way is examined by stationary filtration of gas through it using a gas permeameter equipped with a Hassler core holder. The method consists in determining a constant (stationary) rate of gas filtration through a rock sample in the vertical and six horizontal directions under the influence of a pressure difference. In stationary filtration, the speed is determined by the known volume of gas passing through the sample in a fixed period of time at a constant pressure difference. For uniform distribution of the gas flow over and from the core, permeable screens of various designs are used. A direction parallel to the bedding plane is standardized as horizontal permeability. To study the symmetry of the pore space, horizontal permeability is measured in six directions with a measurement step of 30 °. Measurements in six directions are enough to comprehensively characterize the value of this parameter, since a measurement in one direction, for example 30 ° -210 °, also characterizes permeability in the opposite direction - 210 ° -30 °. Thus, all 360 ° is covered. The direction perpendicular to the bedding plane is standardized as vertical permeability.

Due to the fact that when determining the coefficient of horizontal absolute gas permeability of the core, studies are carried out in six horizontal directions, with six indicators, the informative database is expanded (only two indicators are obtained in the prototype), which means that the subsequent calculation of the absolute gas permeability anisotropy is carried out taking into account all the obtained extended results, which increases the reliability and accuracy of determining the filtration properties of the rock. This is the novelty of the proposed method.

The method of determining the vertical absolute gas permeability coefficient of a core by filtering gas through it in a direction perpendicular to the bedding and the method of determining the vertical absolute gas permeability coefficient of a core by filtering gas through it in directions parallel to the bedding are known.

The essence of the proposed method is illustrated graphically.

Figure 1 shows a sample of a full-sized azimuthally oriented core with a marking of horizontal permeability measurements in six directions with a step of 30 °, with a north-south orientation.

Figure 2 shows the profile of changes in the absolute horizontal gas permeability of the core sample. The diagram shows the measurement directions every 30 °, along which the absolute gas permeability values obtained for each of the directions are plotted. All values of permeability are connected by a broken line characterizing the changes in absolute gas permeability in the directions.

Fig. 3 shows a diagram of the direction of gas filtration through a core sample in a Hassler core holder, (a) vertical permeability measurement; (b) - measurement of horizontal permeability.

The proposed method is implemented on a specific example as follows.

1. Preparation of core samples for analysis.

Samples are made from a core piece with a diameter stored during drilling in the borehole by parallel cutting of the ends and grinding. The ends of the sample should be strictly mutually parallel and perpendicular to the axis of the sample, the optimal height of the sample is 11-15 cm.The depth of the upper and lower ends, the laboratory number of the sample are indicated on the sawn-off black indelible ink, and lines should be drawn through 30 ° corresponding to the filtration directions.

Samples are purified from hydrocarbons by extraction. As solvents, toluene or a mixture of alcohol and benzene in a 1: 1 ratio is used, dried in an oven at a temperature of 105 ° ± 5 ° C and, after drying, cooled and stored in a desiccator over calcined calcium chloride.

The sizes of the samples are determined with a caliper as the average of 3-5 determinations in each direction with an error of up to 0.1 mm.

2. Determination of vertical absolute gas permeability.

In accordance with the diameter of core sample 1, select the desired diameter of the Hassler core holder (Fig. 3), consisting of a casing 3, a lower plunger 4, an upper plunger 5 and a rubber sleeve 2.

Open the upper pneumatic line “from the permeameter” and the lower “to the permeameter”, close the lower “from the permeameter” (Fig. 3, a).

The core sample 1 is loaded into the core holder by installing disk permeable screens 6 between it and the upper lunger 5 and the lower plunger 4.

Create a pressure of lateral crimping of the sample in the range of 350-400 Psi (2.413-2.758 MPa) using a pneumatic system 8.

Set the gas flow through the core sample. The pressure drop ΔP at the inlet and outlet of the sample is measured.

Perform a three-fold measurement of gas flow through sample 1 at various pressure drops. Measurement of gas flow is carried out intermittently in 3-10 minutes, until the gas flow becomes constant.

3. Determination of horizontal absolute gas permeability.

Install vertical permeable screens 6 (Fig. 3, b) on the lower plunger 4 of the core holder diametrically opposite to each other. Each screen 6 should be 1/4 of the core circle.

Close the shutoff valve on the upper plunger 5 of the core holder. Open the lower lines “from the permeameter” and “to the permeameter”. This will ensure the passage of gas from the permeameter through the lower plunger, the right screen 6, the side surface of sample 1, sample 1 - to the left receiving screen 6 and then through the lower plunger 4 (Fig. 3, b.).

Set the sample 1 on the lower plunger 4 between the screens, on top and bottom of the sample set rubber gaskets 7 that do not have an axial hole.

Create a pressure of lateral crimping of the sample in the range of 350-400 Psi (2.413-2.758 MPa) using a pneumatic system 8.

Set the gas flow through the core sample. The pressure drop ΔP at the inlet and outlet of sample 1 is measured.

Perform a three-fold measurement of gas flow through sample 1 at various pressure drops. Measurement of gas flow is carried out intermittently in 3-10 minutes, until the gas flow becomes constant.

After this, sample 1 is rotated 30 ° and all measurements are repeated. In total, 6 measurements of horizontal gas permeability are carried out. For this, the main directions of measurements are marked at the end of the sample (Fig. 1). For an azimuthally oriented core, the north-south orientation line is taken as the reference point.

4. Subsequent analysis of the results of the study and determination of the absolute gas permeability anisotropy.

The coefficient of vertical gas permeability during stationary filtration is calculated by the formula:

where Kv is the coefficient of vertical gas permeability, measured at a given average pressure in the sample, mD (millidars);

µ is the viscosity of the gas under filtration conditions, MPa · s (millipascal-second);

Q is the flow rate of gas passing through the sample, cm ³ / s;

Ra - atmospheric pressure, atm;

ΔР - pressure drop across the sample between inlet and outlet, atm;

P ₁ - excess pressure at the entrance to the sample, atm;

P ₂ - excess pressure at the outlet of the sample, atm;

L is the length of the sample, cm;

F is the cross-sectional area of the sample, cm ² .

The horizontal gas permeability coefficient for each of the six directions in stationary filtration is calculated by the formula:

where Kg is the horizontal gas permeability coefficient, measured at a given average pressure in the sample, mD (millidarsi);

µ is the viscosity of the gas under filtration conditions, MPa · s (millipascal-second);

Q is the flow rate of gas passing through the sample, cm ³ / s;

ΔР - pressure drop across the sample between inlet and outlet, atm;

L is the height of the permeable screen, see

k is the structural coefficient. For permeable screens, each of which covers ¼ of the core surface k = 1.

Then, according to the results of measuring horizontal permeability in six directions, a permeability profile is constructed (Fig. 2).

Vertical anisotropy of absolute gas permeability is defined as the ratio of horizontal absolute gas permeability, determined in one of six directions, to vertical. Thus, six anisotropy values are calculated in each direction.

Horizontal anisotropy of absolute gas permeability is defined as the ratio of maximum absolute gas permeability to minimum, obtained during six measurements.

Studies have shown that the proposed method has a measurement range (1 · 10 ² -5 · 10 ⁴ ) mD and a relative error in determining the absolute gas permeability of 10%.

The proposed method was tested on 35 core samples.

The test results are shown in table 1.

To verify the reliability of measurements by the proposed method, a series of permeability determinations were performed on the same sample (table 2). The measurement results given in this table 2 unequivocally confirm the necessary accuracy of this method.

Thus, the proposed method allows to reliably determine the permeability values vertically and horizontally, while revealing the direction of maximum and minimum filtration.

Claims (3)

1. A method for laboratory determination of absolute gas permeability anisotropy on a full-sized core, including core extraction and drying, its study by gas stationary filtration through it with determination of vertical and horizontal absolute gas permeability coefficients, subsequent analysis of the research results and determination of absolute gas permeability anisotropy, characterized in that when the determination of the coefficient of horizontal absolute gas permeability of the core research is carried out in there are three horizontal directions with a measurement step of 30 °, after which vertical anisotropy is calculated in six directions, as the ratio of the horizontal absolute gas permeability in each direction to the vertical; horizontal anisotropy is also calculated as the ratio of the maximum absolute gas permeability to the minimum, determined from six horizontal directions. 2. The method according to claim 1, characterized in that when determining the coefficient of vertical absolute gas permeability of the core, the gas is filtered through it in a direction perpendicular to the bedding. 3. The method according to claim 1, characterized in that when determining the coefficient of horizontal absolute gas permeability of the core, the gas is filtered through it in a direction parallel to the bedding.

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