SU1677272A1 - Method for oil production out of stratified oil and water bearing pools - Google Patents

Abstract

The invention relates to the oil industry, in particular to methods for extracting oil from oil-bearing deposits of a layered structure, characterized by the presence of adjacent oil and water reservoirs. The goal is to increase the efficiency of the method while expanding the field of application. After an oil reservoir with a low reservoir pressure and an aquifer with a high pressure are opened in the production well, the shutter speed is established to establish an increased pressure in the reservoir. Oscillations are generated in the formation with an amplitude not exceeding the fatigue strength of the rock to stretch, which makes it possible to have a long and predictable effect of pressure fluctuations. 1 tab. with about

Description

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The invention relates to the oil industry, more precisely, to methods for extracting oil from oil-bearing deposits of a layered structure characterized by the presence of adjacent oil and water reservoirs.

The purpose of the invention is to increase the efficiency of the method while expanding its scope.

In the method of extracting oil from a layered oil-bearing reservoir, which includes opening a low-pressure stagnant oil reservoir in the production well and a lower pressure-bearing aquifer with an elevated pressure and extracting formation fluid with excitation of pressure fluctuations, after opening the formations in the production well, time of establishing pressure in the reservoir, and then take the liquid and excite pressure fluctuations with an amplitude within the fatigue strength of ode tensile chetvertvolny and a length not less than a distance between a production well and a power circuit in the reservoir.

A low reservoir stagnant oil reservoir may be present in a layered oil reservoir if it is separated from an adjacent aquifer with elevated pressure by an impermeable interlayer.

The effect of pressure fluctuations on such a formation in a depressed state is ineffective because the formation is practically insensitive to pressure fluctuations due to the low first pressure

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fluid (low formation pressure). Therefore, prior to the initiation of pressure oscillations after an oil reservoir with a low reservoir pressure in the production well and a pressurized aquifer, pressurization is carried out to establish an overpressure in the oil bearing formation. The establishment of increased pressure in an oil-bearing formation increases its elastic response to pressure fluctuations, even with a low amplitude, and creates prerequisites for using such pressure fluctuations to realize dynamic geomechanical effects in order to extract oil from an oil-bearing formation. In this case, the amplitude of pressure fluctuations should not exceed the fatigue strength limit of the rock for stretching, since the number of cycles of wave action on the oil-bearing rock can be in the order of hundreds of thousands of hours or more over the development period of the reservoir. and compression of the breed. At the same time, the tensile strength of the rock is many times less than the rock compressive strength, and the ratio of the rock ultimate strength (under static loading) to the fatigue limit of the same rock under cyclic loading is from 20 to 30. Consequently, the pressure oscillation amplitude in the formation must not exceed one-thirtieth of the rock’s tensile strength, which provides the possibility of a long-term and predictable effect on the oil reservoir by pressure fluctuations for oil recovery.

The choice of a quarter-wave length of not less than the distance between the production well and the feed loop in the oil-bearing formation is explained as follows. At such a wavelength and speed of propagation in the reservoir of a hydrodynamic disturbance, oscillations occur with a frequency of the order of several oscillations or fractions of oscillations per second, which are related to low-frequency oscillations. Excitation of low-frequency oscillations in the formation is characterized by the predominant action of longitudinal vibrations, and transverse oscillations, propagation following longitudinal ones, they are hardly noticeable, since they have a speed that is negligible — the same order as the speed of diffusion processes. At the same time, low-frequency oscillations, longitudinal and transverse, propagate in oil-saturated rocks almost without attenuation, since at low frequencies the attenuation coefficient is close to zero. Therefore, despite the smallness of the pressure fluctuation amplitude used in the method, the depth of the reservoir coverage is significant. At the same time, since longitudinal oscillations are significant, causing a reservoir to oscillate in thickness, and only a single sign oscillates (a small displacement) on the length of a quarter wave, in the case of an oil reservoir coverage from the production well to the power contour

0 only a quarter-wave one, this area of the reservoir will experience cyclical compression in time - thickness stretching. Otherwise, if at a distance from the production well to the feed loop in

5 oil reservoir fit more than a quarter wave. for example, a half-wave or wave wave, then at different distances from the production well, stress and strain would occur almost simultaneously

0 of a different sign, and the movement of pressed oil would become uncontrollable. On the contrary, once the entire oil-bearing interval of the formation is covered by alternating deformations of only one sign in each half cycle

5 oscillations, against the background of the existing pressure drop between the reservoir and the production well, the oil is forced into the production well in a half-cycle of compression, it is replaced by water with

0 power circuit. At the same time, the production rate of the oil reservoir can be quite significant, despite the smallness of the amplitude of pressure fluctuations. This is explained by the fact. that the cyclic compression of the pore volume of the oil reservoir reaches hundreds of thousands of h and millions of cubic meters. In addition, when oscillations are excited in a production well, in which a stagnant oil-bearing and pressure-bearing aquifer is opened, the first of which is located above the second one, the oscillation conductor is an aquifer that has a much higher piezoelectric conductivity than the oil-bearing formation.

The pressure in the aquifer leads to a small vertical downward displacement under the action of elasticity and gravity of the overlying rocks, i.e. clay impermeable proplasty, oil reservoir and

0 nadplast massif rocks. Since the restoration of elastic forces after compression occurs with a delay, in the subsequent half-cycle of pressure reduction, the oil-bearing

5 of the reservoir with squeezing off a part of the oil rushing to the production well under the action of a pressure differential between the reservoir and the production well, since the oil reservoir is subjected to wave action directly in the process of extracting formation fluids from the production well. In the case of low-frequency oscillatory action, which is excited by this method, the requirement to exceed the period of oscillation over the relaxation time of stresses in the rock, which is about 10 s for reservoir rocks, is complied with. Fulfillment of this condition ensures the feasibility of the described oil recovery mechanism according to the method. As can be seen, the method is effective even in the absence of an impermeable layer between the oil-bearing and aquifer strata in the case of oil reservoir stagnation and the possibility of mass transfer through the surface of the oil and aquifer layers when the contact is practically impenetrable.

The method is carried out as follows.

Submitted by drilling, geophysical materials, the results of trial and industrial operation, a stagnant oil reservoir is identified adjacent to a downstream aquifer with increased reservoir pressure but not having a hydrodynamic connection with the oil reservoir along the strike of the formations. This is evidenced by low reservoir pressure in the oil-bearing formation. First, an oil-bearing formation is opened in the production well and the formation pressure is adjusted by the static fluid level in the well. The underlying aquifer with an elevated reservoir pressure is opened and the pressure is restored to an elevated level as a result of the wellbore communication of the formations in the oil-bearing formation. The observations are carried out either through wells located on the supply circuit of the oil-bearing formation, or in the production well itself at the time of establishing the fluid level. Using data on the strength properties of rock formations, the allowable amplitude of pressure fluctuations in the formation is determined, which should not exceed the fatigue strength of the rock by tensile strength. Based on the results of hydrodynamic studies, the rate of disturbance propagation in the oil-bearing and aquifer formations (sound speed) is determined, and taking into account the distance from the production well to the power circuit in the oil-bearing formation, the required value of the period (frequency) of the excited oscillations is determined from the condition that the quarter-wave length is not less distance from the producing well to the feed loop in the oil reservoir.

Considering that the speed of sound in oil-bearing formations may be on the order of 1000 m / s, and the radius of the feed loop may be on the order of 100 m, the required period of pressure fluctuations may take one or several seconds. Pressure fluctuations with such periods are excited when a fluid is taken from a borehole pumping unit as a result of level fluctuations.

0 fluid in the well from periodic suction of fluid as the plunger moves upwards. With a period of oscillations of the same order, pressure fluctuations occur in the well in the process of liquid extraction by the external electrocentrifugal unit. In both cases, the amplitude of pressure fluctuations is of the order of 10 MPa. which, in most cases, is less than the fatigue strength of reservoir rocks by extension, and in these cases it is convenient and technologically effective to excite pressure fluctuations in the production well using the aforementioned liquid extraction devices. In other cases, you can use special

5 hydrodynamic oscillation pathogens, which also function directly in the process of sampling well fluid in the production well.

An example. The method is used for

0 oil production mz layered deposits, composed of stagnant oil-bearing reservoir, aquifer with increased reservoir pressure and permeability and impermeable clay plastic between the reservoir. The depth to the top of the oil-bearing reservoir is 820 m, the thickness of the oil-bearing reservoir is 15 m, the thickness of the aquifer is 25 m, the thickness of the clay seam 3 m.

The oil-bearing reservoir is composed of 10.13 m2 permeability sandstone of 10.13 m2, the aquifer is composed of fine-grained sandstone with a permeability of 3–10 m. Reservoir pressure in the reservoir of 0.15 MPa, reservoir

5 pressure in the aquifer 3.5 MPa. Oil under reservoir conditions has a weak mobility, which is explained by the clay formation of the rock, as well as the presence of paraffin (up to 6 wt.%) In the oil composition and resins

0 (up to 4 wt.%). The low reservoir pressure in the oil-bearing formation is explained by the prolonged production of oil and indicates the absence of hydrodynamic communication between the formations. The feed circuit in the oil reservoir is located 100 m from the production well. According to the data of hydraulic well drilling, the speed of sound in the layers is about 1800 m / s., The maximum recovery time of reservoir pressure in the oil-bearing formation is 21 hours, compressibility

rocks 0.11, rock porosity 0.2, rock strength 24 10 MPa. The radius of the production well is 0.1 m. Since the sound velocity in the reservoir is 1800 m / s and the distance from the production well to the power circuit is 100 m, then for a period of one oscillation T, the wavelength is 1800 x T, and the length quarter-wave must be greater than or equal to 100 m, i.e. the quarter-wave length must be not less than the value found from the ratio 0.25x1800x1,100 (1)

From this it turns out that the period of the wave must satisfy the relation

(2)

tf

This condition is met by pressure fluctuations excited in the production well by a submersible electrocentrifuging unit during the liquid extraction process. Excited oscillations have a period of 2s.

The amplitude of pressure fluctuations in this case is 1, which is less than the limit of the fatigue strength of the rock per tensile strength, which is 8-10 MPa.

The potential flow rate of the oil reservoir using the inventive method can be estimated as follows.

First, the degree of attenuation of the wave in the aquifer is determined, with which the oil-bearing formation is subject to oscillations, using the formula

| P / exp -cUr-Pc), (3)

where lo is the intensity v of oscillations excited in the well;

l (r) is the intensity of oscillations in the reservoir at a distance g from the production well with a radius rc;

a - attenuation coefficient of vibrations in the aquifer.

The values of the coefficient a for longitudinal and transverse waves depend on the oscillation frequency and are derived from the relation

a {9-65). (4)

where f is the oscillation frequency.

Substituting in the ratio (4) f 1 / T 1/2 0.5 s, we obtain

a -0.25 (9-65) (5)

As can be seen from expression (5), the value is almost zero, therefore the exponential function exp - a (g-gc) in formula (3) is equal to one, and therefore formula (3) can be written as

W-.fT (6)

1 g

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The calculation based on the relation (6) is given in the table (with an accuracy of hundredths of a unit).

As follows from the table, a practically noticeable wave action covers a part of the reservoir with a radius of 100 m around the production well, i.e. within the limits of the supply circuit in the oil-bearing formation, and the average value of the attenuation degree in this area of the formation is 1 (g) / 1 0.12. Taking into account the fact that the maximum amplitude of pressure fluctuations (in the well) is 1, MPa, we obtain, taking into account the average degree of attenuation, the average amplitude of pressure fluctuations in the formation 1, x 0.12 0.18 10 3 MPa.

The length of time over which a quarter-wave area of an oil-bearing formation reaches a radius of 100 m with a disturbance propagation speed of 1800 m / s is 100: 1800 0.06 s, i.e. the coverage occurs almost instantaneously, therefore, the considered area of the reservoir is subjected to oscillating release of oil with the same vibrational filling of the pressed volume of oil with water from the supply circuit against the background of the steady-state pressure differential between the reservoir and the producing well.

Since the absolute value of compression is small and is in the elastic region of deformation, the change in the hole volume is described by a known relation.

AV m / 3V0AP. (7)

where a v is the change in the reference volume;

m is rock porosity; / 3 - coefficient of elastic compressibility of the rock;

Vo is the initial reservoir volume;

DR is the average amplitude of pressure fluctuations in the reservoir.

Substituting in the relation (7) the numerical values of the quantities, we get the amount of once squeezed oil

L V 0.2 x 47-U4 x 0, 10 0.0017 m3 (8)

Since during one oscillation the compression process is performed twice (in two quarter-waves), and the period of one oscillation is 2 seconds, then within a day oil is obtained potentially

0.0017 x 2 x 86400: 2 147 m3. (9)

However, since the flow radius around the production well is one to two orders of magnitude smaller than the radius of the feed loop, towards which part of the oil can also be pressed, the potential flow rate of one production well may be

respectively, a smaller value, i.e. from 1.47-14.7 m3 per day. In order to select the entire potential production rate of the oil reservoir, the method is used in all production wells located in the considered area.

After the formations are opened in the production well, the exposure is performed for 48 hours, which is longer than the maximum time for an oil-bearing formation to establish increased pressure (21 hours), and then fluid is withdrawn from the well with excitation of pressure fluctuations using a submersible electrical centrifugal plant.

Claims (1)

Claims of Invention A method for extracting oil from a layered oil-bearing reservoir, comprising opening a stagnant low-pressure stratum oil-bearing formation and an underlying aquifer with elevated pressure in the production well and selecting reservoir fluid with excitation of pressure oscillations, characterized in that, in order to increase the efficiency of the method while expanding its field of application, after opening the formations in the production well, they are timed to establish an increased pressure in the oil-bearing formation, and when the formation fluid is withdrawn, pressure oscillations are excited with amplitude within fatigue strength of the rock for stretching and with a quarter-wave length not less than the distance between the production well and the feed loop in the oil-bearing formation.