EA005148B1 - Device for the acoustic action on a oil and gas-bearing formation - Google Patents

Abstract

A device for acoustic action on an oil and gas-bearing formation, comprising a well arrangement provided with two or more acoustic radiators (1) which are arranged in the lower part thereon and open to the environment by means of windows embodied in the walls of a logging instrument body, each radiator is provided with two reflectors in the form of cone (12) which are coaxially arranged in an individual manner on both sides of the end of the radiator, the height of the cone is equal to the radius of the reflector, the top thereof having an angle of 90 degree being oriented towards said reflector; the distance between the ends of the adjacent conical reflectors (12) d ranges from 2 mm to 10 % of the height thereof, the distance from the end of the radiator (1) to the top of the reflector (12) being selected according to the condition of maximum transmission of a mean power to the formation and calculated in accordance with the following formula: A = n λ/8-R; wherein: n= 1,5,9...; λ is an acoustic wavelength; R is the internal radius of a well tube; each acoustical reflector is formed by two identical piezo packages (2) and (3) having a length equal to a quarter length of the acoustic wave in the piezo element material. Said piezo packages are provided with a common fixing base (4) disposed therebetween, the lateral piezo elements of the piezo packages (2) and (3) having an equal polarity.

Description

The invention relates to the oil and gas industry and can be used in the extraction of oil.

A device for influencing the bottomhole zone of the reservoir, patent of the Russian Federation No. 2026970, publ. 20.01.95, bull. No. 2, MKI E21V 43/25, containing a ground unit, connected by cable to a downhole device, in the lower part of which an acoustic emitter is located, operating in a closed housing filled with transformer oil. During the operation of such a radiator, there are large losses of acoustic power and it cannot be used to affect the entire productive formation in the process of oil production.

A device adopted as a prototype for acoustic impact on a petroleum reservoir is known, RF Patent No. 2140519, MKI E 12 V 28 / 00.43 / 25, whose acoustic emitter communicates directly with the environment and is equipped with a conical reflector to turn an acoustic wave from a vertical in the horizontal direction of propagation through the reservoir. The effectiveness of such a device is higher than the previous one, it increases the fluidity of oil, but does not create directional flows, which is very important during production.

DISCLOSURE OF INVENTION

The challenge is to develop a device for acoustic impact on the oil and gas reservoir, which creates a directional movement of oil layers in the reservoir to the production wells, thereby increasing the efficiency and productivity of production.

The task with the achievement of this technical result is solved due to the fact that in the device for acoustic impact on the oil and gas reservoir containing a downhole tool, in the lower part of which two or more acoustic emitters communicating with the environment are placed, each of which is equipped with two one on both sides of the ends of the radiator with reflectors, in the form of a cone with a height equal to the diameter of the acoustic radiator, with an apex angle of 90 ° facing the radiator, distance m Between the ends of adjacent conical reflectors ά is from 2 mm to 10% of the height of the conical reflector, and the distance A from the end of the radiator to the top of the reflector is selected from the condition of maximum transfer of average power to the formation and calculated by the formula:

A = ηλ / 8 - B, where η = 1, 5, 9 ...;

λ is the acoustic wavelength;

B is the inner radius of the borehole pipe; each acoustic emitter is formed by two identical piezopacks with a quarter-wavelength sound wavelength of the piezoelectric material assembled from piezoelectric elements with a common fixed base for fixing piezopacks located between them, with the extreme piezoelectric elements of the piezoelectric packages having the same polarity.

Device operation option

The operation of the device and the propagation of acoustic waves is illustrated by the drawings:

FIG. 1 - a general view of an acoustic emitter;

FIG. 2 is a view A, an enlarged image of the end of an acoustic emitter with a conical reflector;

FIG. 3 - a general view of the device.

Each acoustic emitter 1 is assembled from two identical piezopacks 2 and 3, having a common fixed base of fastening 4, located between them, and the extreme piezoelectric elements of piezopacks 5, 6, 7, 8 have the same polarity (identical polarization state "plus or minus") . As a result of this, as well as coaxial arrangement of piezopacks 2 and 3, when exposed to an electric field, the deformations occurring at the ends 5 and 8, 6 and 7 of the acoustic emitter 1 have opposite directions along the axis, and do not create pressure on the base and the case waves 9 and 10 propagate in antiphase, the length of the piezopackage 1 at the speed of sound in the material of the piezoelectric element C = 3.5 cm / s and the frequency of the generator 1 = 7.5 kHz is 1 = λ / 4 = Οχί / 4 = 11.6 cm.

From the drawings of FIG. 2 and FIG. 3 shows that two or more piezoceramic acoustic emitters 1 are placed on the casing of the downhole device 11 on each side of each emitter, coaxially with it at a fixed distance A from each of its ends, the top of the conical reflector 12 is located opposite the conical reflectors 12 in the device 11 Windows 13 are made for communication with the environment, the distance between the ends of the conical reflectors is ά. Acoustic wave travels from the acoustic emitter 1 to the inner wall of the borehole pipe 14, which is equal to A + B. By selecting the distance A, it is possible to choose the phase in which the incident acoustic wave approaches the inner wall of the well pipe, and therefore the optimal variant of pressure and velocity amplitudes.

Acoustic waves from the end of the emitter 1 to the conical surface of the reflector 12 pass along the path A, or D1, or a ₂ , or ..., or a _p , then they change their direction perpendicular to the axis, reflected from the conical surface of the reflector 12 and go the way to the inner wall of the borehole pipe 14, respectively, B, or in _b, or ₂ , or ..., or _p . Sinusoid 15 shows the deviation of the pressure of the medium P, and sinusoid 16 shows the oscillation of the velocity of particles of the medium V in the acoustic wave, which is ahead of pressure fluctuations by π / 4, a quarter of the period.

The total distances A + B, and ₁ + in ₁ , and ₂ + in ₂ ... and _n + in _n are equal to each other, since the angle at the top of the reflector 3 is 90%, i.e. А + В = а ₁ + в ₁ = а ₂ + в ₂ = .... = а _п + в _п = А + Я, В = Я, and Я is the inner radius of the well pipe.

As a result of this design, all the incident acoustic waves from the end of the radiator to the downhole pipe come in one phase, and the axial direction piston wave turns into a ring ring, moving in a horizontal direction perpendicular to the axis from the radiation source. By changing the distance A = ολ / 8 - можно I can achieve the optimal option for different values of the radius of the borehole pipe. The choice of the wave phase corresponding to ολ / 8 with n = 1, 5, 9 ... on the border with the inner wall of the well pipe increases the efficiency of the entire device, due to the maximum return of the average power to the reservoir, because at these times, the sinusoidal deviations of the pressure of the medium 15 (P) and the velocity 16 (V) intersect and have the same signs.

When the device operates, acoustic radiation reflected from conical reflectors turns into plane waves, in which the fronts or surfaces of equal phases are planes moving in the direction of wave propagation with a certain speed and separates the working layer into flat ring zones, or waveguides, in which Flat-ring flows in the form of plane acoustic waves propagate. Since wave propagation is possible in layers bounded not only by rigid walls, but also by moving media, with different sound velocities, which is the fluid of the oil reservoir where different rocks are present, therefore the effect of separation into zones-belts created by the device is possible in the reservoir with fluid. As shown in FIG. 3 as a result of the operation of the device, layers are formed in the reservoir, representing flat-ring flows ί and _), created by a wave of acoustic deformation, and a layer formed by them. Layer ί is a plane-ring wave formed after reflection of a piston wave from a conical reflector, layer _) is a deformation zone due to radial oscillations of acoustic emitters at a frequency different than in the axial direction, with different values of the amplitude of change in pressure and particle velocity than in the ί layer, the ά layer appears as a result of the ejection effect; from the action of counter-directed amplitudes of pressures created by the waves of a pair of layers ί, similarly, the conditions of fluid ejection are also created at the boundaries of the layers ί-f _) - ί, ί-ά and ά-ί. The ejection speed can be adjusted by varying the distance ά between the ends of the adjacent conical reflectors within the specified values from 2 mm to 10%, the height of the reflector, the limiting values of the distance ά lead to the absence of the ejection effect when the device is operating. The creation of an ejection layer ά is also promoted by the vibration accelerations of the order of 100-500d, which arise when a sinusoidal change in the supply voltage of the emitters. These accelerations and the passage of acoustic pressure waves through the layers of the reservoir lead to the complete removal of viscous frictional forces of fluid motion in the pores of the formation matrix due to the deformation of the pores. In the layers ί, _) and ά, conditions are created for the directional filtration of the fluid and its layer-by-layer movement to the effluent wells. Along with this, a decrease in the viscosity of the moving fluid also occurs, which, together with directed filtration, leads to an increase in oil recovery of the reservoir as a whole.

Industrial Applicability

Thus, when the device is in operation, acoustic energy is pumped into the formation depending on the device’s structural length (the number and dimensions of the installed emitters), a powerful directional movement of oil to the production wells is created, and the device can be used as the main oil-producing equipment, which increases the oil output and increases the flow rate by 2 or more times.

Prototype samples of the device have passed tests at the fields of OJSC Tubukneft and Surgutneftegaz.

Claims (1)

CLAIM Device for acoustic impact on the oil and gas reservoir, containing a downhole tool, in the lower part of which two or more acoustic emitters communicating with the environment are placed through windows in the body of the downhole tool, each of which is equipped with two, installed coaxially one on both sides of the radiator ends , reflectors in the form of a cone, with a height equal to the diameter of the acoustic emitter, with an apex angle of 90 °, facing the radiator, the distance between the ends of adjacent conical reflectors leu ά ranges from 2 mm to 10% of the height of the conical reflector, and the distance A from the end of the radiator to the top of the reflector is selected from the condition of maximum transfer of average power to the formation and calculated by the formula: A = PA8-Z, where n = 1, 5, 9 ...; λ is the acoustic wavelength; K - the inner radius of the well pipe; each acoustic transducer is formed by two identical piezopacks, a quarter of the length of the sound wave in the piezoelectric material, having a common fixed fixing base located between them, and the extreme piezoelectric piezopacks have the same polarity.