RU2655007C1 - Method of the rocks pressurometer testing - Google Patents

Abstract

FIELD: drilling of soil or rock.

SUBSTANCE: invention relates to the wells studying method and can be used to determine the rocks physical and mechanical properties in their natural occurrence. Method comprises loading the well walls with the increasing pressure steps by supplying of the fluid predetermined amounts to the pressurometer probe. Measuring the changed pressure and the well walls displacements. At that, the well walls loading is carried out in the interval containing the hydrofracturing closed fracture. This fracture is opened by increasing the loading pressure and using the measured hydrofracturing fracture opening pressure in calculating of the rocks deformation properties.

EFFECT: technical result consists in increase in the open wells pressurometer studies informativeness and reliability with obtaining additional information about the rocks physical and mechanical properties in their natural occurrence.

10 cl, 1 dwg

Description

The invention relates to methods for researching wells and can be used to determine the physico-mechanical properties of rocks in their natural occurrence. Reliable determination of rock properties allows efficient and safe development of mineral deposits, land and underground construction in difficult mining and technological conditions.

A known method of pressiometric testing of soils, including loading the walls of the well with radial pressure, measuring the resulting movements of the shell of the elastic chamber of the probe and determining the shear modulus (see Trofimenkov Yu.G., Vorobkov LN Field methods for studying the construction properties of soils. - M. : Stroyizdat, 1981 - p. 152.). The interpretation of the obtained data and the determination of the elastic moduli are based on the solution of the Lame problem for a thick-walled infinitely long pipe under the influence of internal pressure. It is believed that the inner diameter of the pipe is equal to the diameter of the well, and the outer diameter of the pipe corresponds to the zone of influence of the downhole probe on the rock mass. This solution does not take into account the possible heterogeneity of the soil, its compaction and deformation of the pore space when a load is applied to the walls of the well.

Also known is a modification of this method using devices with a sector load application (see GOST 20276-2012, Appendix A), which includes loading the walls of the well by expanding two steel punches-dies located on diametrically opposite sides of the device and determining the deformation properties according to the results of subsequent unloading .

The disadvantages of this method include the impossibility of direct measurements of the load transmitted directly to the borehole walls by each sector of the pressiometer, as well as the complexity of technical solutions by which it is possible to realize measurements of linear displacements of the borehole walls under the influence of this load.

The common problems of the given pressiometric methods include the fact that for most practical problems it is necessary to know not the shear modulus determined by this method, but the Young's modulus, for the calculation of which, when interpreting the results of the pressiometric tests, the Poisson coefficient of the host rocks is used. Most often, the value of the Poisson's ratio is taken from tabular data, which reduces the reliability of the methods under consideration and can lead to incorrect technological solutions. Another common drawback is the approximation adopted in the above methods, according to which, under the load of the studied interval, the well contour is deformed uniformly and described by a circle with a certain radius. Such a loading model does not take into account possible deformation of the well walls in an uneven stress field, as a result of which its contour takes the form of an ellipse.

Closest to the proposed invention in technical essence and the achieved result is a known method of pressiometric testing of rocks and rocky soils according to patent SU 1785548 (IPC E02D 1/00, publ. 12/30/1991), including the load of the walls of the well with increasing pressure steps with different exposure times for various types of enclosing rocks, determining the reduced time and plotting the relative displacement of the rock in the borehole wall from the reduced time. The disadvantages of the known method according to patent SU 1785548 include the use of parameters in the calculation formulas, for the calculation of which it is necessary to conduct additional studies of samples in laboratory conditions, which reduces the productivity of the method and increases the cost of work.

The technical problems to be solved in the present invention are to expand the capabilities of known methods of pressiometric studies of open-hole wells, to obtain additional information about the physicomechanical properties of rocks in their natural occurrence.

The tasks are solved by the fact that in the method of pressiometric testing of rocks, which includes loading the walls of the well with steps of increasing pressure by supplying specified volumes of fluid to the pressiometric probe, measuring the changed pressure and displacements of the walls of the well at the time of stopping the flow of fluid, calculating rock parameters from the measured data, according to the technical solution, the loading of the walls of the well is carried out in the interval containing a closed hydraulic fracture, this crack is opened due to eniya loading pressure, and use the measured crack opening pressure of the fracturing in the calculations of the deformation properties of rocks.

Such a combination of essential features makes it possible to increase the information content and reliability of the pressiometric methods for testing rocks, and makes it possible to obtain additional data on the near-wellbore area in the massif affected by the development of a hydraulic fracture. The presence of an open fracture fracture on the well contour leads to a change in the nature of the dependence of the displacement of the well walls on the applied load recorded during the experiment, which provides additional information about the surrounding rocks. In the pressiometric diagram, the beginning of the crack opening corresponds to the transition point of the linear section of the deformation of the well with a continuous contour in the nonlinear section of the incomplete opening of the existing hydraulic fracture.

Hydraulic fracture can be directed along the axis of the well, which allows it to open at lower pressures in the pressiometric probe, or across the axis of the well, and the walls of the well are additionally loaded along the axis of the well with an increasing tangential load and this load is measured, which allows determining the mountain load acting along the axis of the well pressure and use it to calculate the deformation properties of rocks.

For hydraulic fracturing, the locking pressure measured during hydraulic fracturing can be known, and it can be used in calculating the deformation properties of rocks, which allows expanding the capabilities of the method of pressiometric testing by additionally determining the minimum effective stress σ _min .

Calculations of the deformation properties of rocks can be performed according to the data measured with an open or incompletely opened hydraulic fracture, or when loading of the walls of the well is carried out in the interval containing a directed hydraulic fracture of a known orientation, or in two closely spaced intervals containing directed hydraulic fractures with different friend from each other by known orientations, which leads to additional information on the near-wellbore region of rocks affected by the development of a fracture us fracture and increases the reliability and capabilities of the method.

To calculate the deformation properties of rocks, two areas of the pressiometric curve ΔR (P) can be used, one of which corresponds to the loading of the well walls to the fracture opening pressure of the hydraulic fracture, and the other above it, which expands the capabilities of the pressiometric test method and increases its efficiency:

where ΔR (P) is the pressiometric curve describing the change in the radius of the well ΔR under load P;

C ₁ (E, ν) and C ₂ (E, ν) are functions depending on the Young's modulus E and Poisson's ratio ν;

A (R ₀ , P ₀ , σ _min , σ _max ) is a function depending on the initial value of the radius of the well R ₀ at the initial pressure P ₀ , minimum σ _min and maximum σ _max compressive stresses in the rocks;

B (R ₀ , P ₀ , σ _min , σ _max , P _r ) is a function depending on the variables R ₀ , P ₀ , σ _min and σ _max , as well as the fracture opening pressure P _r .

The proposed method is illustrated in FIG. 1. For research, drill a well 1, into which, using a pipe string 5, or in another way, a pressiometric probe 4 is delivered at a predetermined distance from the wellhead. The pressiometric probe has one or more elastic chambers, and can be equipped with sensors for measuring the movements of the probe shell. The total length of the probe chambers must be at least four of their diameters, and the borehole diameter must not exceed the probe diameter by more than 10 mm.

In this well, in a given measurement interval, a hydraulic fracture 3 is created in advance using known methods and technical solutions, which can be directed along or across the axis of the well, and the shut-off pressure of which can be known from the results of hydraulic fracturing and used to calculate the deformation properties of rocks. A crack can be created by directional fracturing and have a known orientation, or there can be two such cracks in closely spaced intervals, and their orientation will be different.

Then, pressure is applied through pipes 5 to the pressiometric probe until the probe shell contacts the well walls and the initial radius of the well R ₀ is determined, with respect to which the deformation of the well walls is subsequently measured. Next, they start loading the walls of the well with pressure steps, while the pressure in the probe chamber must be measured with an error of no more than 5% of the step, and the pressure value at each stage and the duration of this pressure are selected based on the type of rock. In the process of loading, the existing hydraulic fracture 3 opens up with the formation of region 2, in which the crack faces do not touch each other. According to the test data, a graph of the dependence of the movement of the walls of the well on the pressure in the pressiometric probe is built.

On the graph, an averaging line is drawn by the least squares method or by the graphical method. The first point to be included in the averaging is the point corresponding to the moment of complete compression of the bumps in the borehole walls, which is the beginning of the linear section of the graph. For the end point bounding the linear plot, take the point corresponding to the moment of opening of the fracture at a pressure P _r . A further increase in pressure in the probe leads to data being obtained when the hydraulic fracture is opened, or when the hydraulic fracture is not open to the full length.

To calculate the deformation properties of rocks, two areas of the pressiometric curve ΔR (P) are used, one of which corresponds to the loading of the borehole walls to the fracture opening pressure of the hydraulic fracture, and the other above it

where ΔR (P) is the pressiometric curve describing the change in the radius of the well ΔR under load P;

C ₁ (E, ν) and C ₂ (E, ν) are functions depending on the Young's modulus E and Poisson's ratio ν;

A (R ₀ , P ₀ , σ _min , σ _max ) is a function depending on the initial value of the radius of the well R ₀ at the initial pressure P ₀ , minimum σ _min and maximum σ _max compressive stresses in the rocks;

B (R ₀ , P ₀ , σ _min , σ _max , P _r ) is a function depending on the variables R ₀ , P ₀ , σ _min and σ _max , as well as the fracture opening pressure P _r .

The joint solution of these equations makes it possible to determine the Young's modulus E and the Poisson's ratio ν of rocks at their location.

Thus, supplementing the usual studies of a well with a continuous contour with studies of the same well with an open fracture, it is possible to expand the capabilities of existing methods of pressiometric testing, to increase the efficiency and reliability of determining the physicomechanical properties of rocks.

Claims (15)

1. A method of pressiometric testing of rocks, including loading the walls of the well with steps of increasing pressure by supplying specified volumes of fluid to the pressiometric probe, measuring the changed pressure and displacements of the walls of the well at the time of stopping the flow of fluid, calculating rock parameters from the measured data, characterized in that the loading the walls of the well are carried out in an interval containing a closed hydraulic fracture, open this crack by increasing the loading pressure and use measured e is the fracture crack opening pressure in calculating the deformation properties of rocks. 2. The method according to p. 1, characterized in that the fracture is directed along the axis of the well. 3. The method according to p. 1, characterized in that the hydraulic fracture is directed across the axis of the well, and the walls of the well are additionally loaded along the axis of the well with an increasing tangential load and this load is measured. 4. The method according to p. 1, characterized in that for the fracture is known locking pressure, measured when performing hydraulic fracturing. 5. The method according to p. 4, characterized in that the locking pressure of the fracture is used in the calculations of the deformation properties of rocks. 6. The method according to p. 1, characterized in that the calculations of the deformation properties of the rocks are performed according to the data measured with the fracture opened. 7. The method according to p. 1, characterized in that the fracture is not disclosed to the entire length. 8. The method according to p. 1, characterized in that the loading of the walls of the well is carried out in the interval containing a directional fracturing crack of known orientation. 9. The method according to p. 8, characterized in that the loading of the walls of the well is carried out in two closely spaced intervals containing directed fractures with different known orientations. 10. The method according to p. 1, characterized in that for calculating the deformation properties of the rocks using two areas of the pressiometric curve, one of which corresponds to the loading of the walls of the well to the pressure of the opening of the fracture, and the other above it

Where

- pressiometric curve describing the change in the radius of the well

under load

;

and

- functions dependent on Young's modulus

and Poisson's ratio

;

- function depending on the initial value of the radius of the well

at initial pressure

minimum

and maximum

compressive stresses in rocks;

- variable dependent function

,

,

and

as well as fracture crack opening pressure

.

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