RU2789492C1 - Method for generating and modulating pressure waves in an injection wellbore and a device for its implementation - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: group of inventions relates to a method for generating and modulating pressure waves in an injection wellbore and a device for its implementation. The method for generating pressure waves in an injection wellbore includes installing a device for generating and modulating pressure waves at the lower end of the tubing, supplying fluid through an inlet nozzle to a cylindrical chamber. A jet of liquid is directed through the rings to the outlet. A jet of liquid is formed in the space between the bottoms. Primary pressure fluctuations are generated at two high close frequencies when the jet flows through the rings. Create low frequency beats and excite resonance in the cylindrical chamber at a beat frequency corresponding to the natural frequency of the cylindrical chamber. A low-frequency pressure wave is formed behind the outlet in the well annulus at the beat frequency.

EFFECT: technical result consists in increasing the efficiency of pressure fluctuations, in increasing the mobility of fluids in the bottomhole formation space, in increasing the mechanical effect on solid deposits on the walls of the well when a technical fluid is injected into it.

2 cl, 3 dwg

Description

SUBSTANCE: group of inventions relates to the oil industry, namely to a method and device for generating pressure waves in the annulus of an injection well, designed to clean the walls of wells and perforations from solid deposits, decolmatize the bottomhole formation zone and increase the mobility of formation fluids.

It is known that the injection of fluid into the reservoir at a late stage of development increases the flow rate of production wells. It is also known that the creation of pressure fluctuations in the adjacent section of the formation contributes to the release of capillary pinched oil, decolmatation of the bottomhole zone, which also leads to an increase in the flow rate of production wells. The injection of liquid into the reservoir is carried out through several injection wells located around the production well.

The most effective methods for creating pressure fluctuations at the bottom of the well are using for this purpose hydrodynamic generators installed directly in the place where they are most in demand, i.e. at the lower end of the tubing (tubing). The pressure waves generated by these devices attenuate rather quickly, and therefore it is desirable to place them in close proximity to the target, namely, perforation holes in the casing pipes and the bottomhole formation zone.

With this method of generating pressure fluctuations, the entire liquid is pumped through a hydrodynamic generator, which in one way or another creates pressure fluctuations in the liquid flowing through it, spreading its effect to the surrounding area. The pumped fluid then enters the formation. The rigid design of jet generators and the absence of parts moving during operation is their advantage.

The disadvantage of hydrodynamic generators is the impossibility of generating low-frequency pressure waves in a limited volume at high fluid supply pressure, since very large resonators are required to amplify low-frequency elastic waves. Also, the disadvantage of the hydrodynamic generator is the presence of a rigid structure, which makes it difficult to reconfigure the resonant frequency without a significant change in the entire structure.

Devices and methods for generating and modulating pressure waves in a fluid flow are known, in which a combined acoustic oscillatory system is assembled and jet generators are used. So, for example, in patents [RU2637008, publ. 11/29/2017 and RU2637009, publ. 11/29/2017], devices are described that are two independent oscillatory systems. One part of the multi-frequency oscillatory system is tuned to generate, amplify and form a high-frequency wave of one frequency, and the other part of the oscillatory system is tuned to another frequency. In this case, the system is installed in the well. After it, parallel high-frequency waves of two different frequencies are formed, interacting with each other and forming, as a result of modulation in the near field, a low-frequency difference frequency wave, which is amplified in a low-frequency cavity resonator and sent to the injection wellbore.

In the patent [RU2653205, publ. 05/07/2018] also describes a group of inventions designed to clean the walls of the well from solid deposits. A method for generating and modulating pressure waves in a fluid flow is described, in which a combined acoustic oscillatory system is assembled, consisting of two combined acoustic oscillatory systems. In this case, the external acoustic oscillatory system is a Helmholtz jet oscillator and includes an inlet nozzle, a resonator chamber and an exhaust channel. The internal acoustic oscillatory system is a Galton whistle and includes an input nozzle and a resonator sleeve. Moreover, both acoustic oscillatory systems are simultaneously excited by a single gas jet supplied from a common annular nozzle to the sharp input edges of the exhaust channel and resonator bushing, respectively. The annular nozzle is connected to the channel of the tubing and gas is supplied to the well through it, a gas jet is arranged behind the annular nozzle and directed to the sharp inlet edges of the exhaust channel and the resonator sleeve. Pressure fluctuations are generated at the sharp inlet edges of the exhaust channel and their amplitude is increased in the resonator chamber. High-frequency pressure oscillations are generated at the sharp input edges of the resonator sleeve and amplify their amplitude in the resonator sleeve. Low-frequency pressure fluctuations are generated at the sharp input edges of the exhaust channel and their amplitude is increased in the resonator chamber. A wave packet is formed at the output of the combined acoustic oscillatory system, including pressure waves of high and low frequency, they are mutually modulated to form a difference frequency wave, the amplitude of which is amplified behind the exhaust channel and directed to the bottomhole formation space through perforations in the casing wall.

To generate pressure waves in the annulus of the well known [US4041984, publ. 08/16/1977] method and device, consisting of a cylindrical body with two parallel bottoms; an inlet nozzle located in the center of the front bottom; an outlet located coaxially with the inlet nozzle in the center of the rear bottom; the inlet nozzle is connected to the tubing, and the outlet is directed down the well, while the distance between the holes and the volume of the chamber are scaled with the size of the inlet, and the natural frequency of the chamber corresponds to the Helmholtz frequency.

The method is carried out as follows: water is pumped into the well and a liquid generator (the claimed device) with a jet drive is placed. The inlet is connected during operation to a source of constant fluid flow, such as a conventional pump and accumulator, so that the fluid flowing into the chamber through the inlet has a constant speed, at a diameter D ₁ . As the fluid enters the chamber through the diameter, it continues to move towards the exit. However, as the liquid leaves the diameter D ₁ , a vortex ring begins to develop, the average diameter of which eventually exceeds the diameter D ₂ of the outlet, and therefore part of the liquid enters the end chamber surrounding the outlet. A pressure wave is created at the outlet, which then propagates towards the inlet at the speed of sound in the liquid. Since the vortices are not continuous, i.e. spaced apart during their movement from D ₁ to D ₂ , changes in the energy level of the jet stream will be fluctuating. As the energy level increase reaches the outlet, the output flow will increase and vice versa. In this case, a constant input flow, proportional to the Helmholtz frequency and jet length, leads to an oscillating output flow and pressure fluctuations inside the chamber at approximately the Helmholtz frequency. Thus, the output stream is a pulsating stream. The pressure inside the chamber also fluctuates, and as the jet speed gradually increases, regions arise in which large fluctuations in flow and pressure are observed. The disadvantage of this method of generating pressure waves is the impossibility of modulating the frequency of pressure fluctuations of the outlet stream.

To generate pressure waves in the annulus of the well, it is known [RU2122109, publ. 11/20/1998] an invention in which the method is carried out as follows: water is pumped into the well (without activators and special heating), necessary to replace oil in the reservoir and maintain reservoir pressure. When water flows through a hydrodynamic emitter, part of the energy of the water flow is converted into elastic vibrations in the frequency range from 1 to 45 kHz, which act on the oil reservoir. In this case, decolmatation of the bottomhole zone of the injection well occurs, the release of capillary-substituted oil, which leads to the alignment of the oil replacement front with water and an increase in oil recovery of productive formations by 10-90%. The method provides for the production of too high frequency pressure oscillations in the technical liquid flow. As is known, the impact on the reservoir by high frequency pressure fluctuations is ineffective.

To generate pressure fluctuations in a fluid flow, [US6029746, publ. 29.02.2000] method and device, which is a hollow body of revolution and consisting of a chamber, an inlet nozzle and an outlet located coaxially with a certain interval. This device is called a Helmholtz jet oscillator (SHO). The device consists of two relatively independent elements. The inlet nozzle, liquid jet and outlet form a jet pressure oscillation generator, which also functions in the absence of a resonator chamber, although the amplitude of the generated pressure oscillations is very small. The resonator amplifies the pressure fluctuations created by some other device, since the liquid column enclosed in it is almost stationary. The generator is active, it itself creates pressure fluctuations, since it contains a high-speed jet that has a reserve of kinetic energy for this. The resonator is passive, it only responds, i.e. amplifies the pressure fluctuations created by some other device, since the liquid column enclosed in it is almost stationary. The method for generating pressure fluctuations is carried out as follows: the device is lowered into a well filled with an annular fluid along a work string at preselected speeds and pressures to provide a resonant frequency of vibrations in the chamber. Vortices and damped pressure pulsations in the liquid exit the oscillating chamber through a central hole in the bottom of the chamber and are discharged through the device outlets. The ejected fluid creates a pulsating shock wave in the fluid of the annulus in the well. The pulsating shock wave subjects the perforations to pressure changes that induce cyclic tensile and compressive stresses in them and destroy the material occluding the perforations and the well. In addition, pressure waves break up parts of the formation and stimulate the well to recover. The time that the treatment device remains near the hole depends on the properties of the formation. The disadvantage of these devices and the method is the generation of pressure oscillations at one frequency, which eliminates the possibility of periodic low-frequency bursts of oscillation amplitude.

A known method of generating pressure waves in the annulus of the well, implemented in the device [Experimental study of the Helmholtz oscillator controlled by the jet. Translation of VCP No. B-56251 from J. Fluid Engineering, 1979, 101, IX, No. 3, 383-390], in which a Helmholtz jet oscillator is installed at the lower end of the tubing (tubing) consisting of a cylindrical chamber bounded by two parallel bottoms, with an inlet nozzle located in the center of the downstream bottom on the axis of the cylindrical chamber and connected to the tubing channel, with an outlet located in the center of the downstream bottom on the axis of the cylindrical chamber and directed into the annulus of the injection wells, at the same time, supply fluid through the inlet nozzle to the cylindrical chamber, direct the fluid jet to the outlet, form a fluid jet with a perturbed periphery in the space between the bottoms and generate primary pressure fluctuations when the jet flows through the outlet, amplify the primary pressure fluctuations in the cylindrical chamber due to the excitation of resonance at the frequency of its own oscillations, which is tuned constructively during the production of a cylindrical chamber, pressure waves are formed behind the outlet in the annulus of the well.

The jet oscillator is designed to convert the kinetic energy of the flow into vibrational energy. The acoustic resonator is designed to selectively amplify pressure fluctuations of a certain frequency. The process of generation of pressure fluctuations in the flow begins, as a rule, with the acceleration of the flow, since the amplitude of pressure fluctuations increases with the increase in the velocity head of the jet. The flow is accelerated in the inlet nozzle, which, in addition to increasing the speed, also serves to form a jet of one form or another: round, flat, annular. Behind the nozzle exit, an unconstrained free jet moves in the volume of the resonator chamber between the caps. When flowing through the outlet, the jet touches its sharp inner edge with its perturbed periphery. This produces small local pressure perturbations of small amplitude in the region of the edge. The resonator chamber serves to amplify these primary pressure fluctuations. To amplify the primary local pressure oscillations inside the resonator chamber, it is necessary to match the frequency of primary pressure oscillations (POP) with the natural oscillation frequency (FFR) of the liquid column enclosed in the resonator chamber. In other words, we can say that two parts of one device must be tuned in unison.

The disadvantage of this method of generating pressure waves in the annulus is the high frequency of pressure fluctuations when generated under conditions of a limited resonator volume.

Known method and device for generating pressure waves in the wellbore of an injection well [RU2670623, publ. October 24, 2018], designed to clean the walls of casing pipes and perforations from solid deposits, decolmatize the bottomhole formation zone and increase the mobility of formation fluids. A borehole acoustic emitter for generating pressure waves in a fluid flow is a hollow body of revolution and consists of: a cylindrical chamber with two flat bottoms; an axisymmetric nozzle made in the center of the front bottom and an outlet with a sharp edge made coaxially to the nozzle in the center of the rear bottom. The nozzle includes a tapering accelerating section and a cylindrical leveling section ending with a flat nozzle cut orthogonal to the nozzle axis. In this case, the geometry of the tapering accelerating section is smoothly associated with the geometry of the cylindrical leveling section without a break in the nozzle contour. In this case, a flat nozzle cut is located on the inner wall of the front cover.

The disadvantage of the device and method for generating pressure waves in the annulus is an increase in the jet flow rate, which, in turn, leads to insufficient cleaning of the perforations in the casing and the bottomhole formation zone.

A known method and device for generating pressure waves in the wellbore of an injection well [RU2572250, publ. 01/10/2016], taken by the applicant for the prototype. This method of generating pressure waves at the bottom of the well is characterized by the fact that a Helmholtz jet oscillator (JOG) is installed at the lower end of the tubing (tubing) channel, which is a hollow body of revolution and consists of: a cylindrical chamber with two parallel bottoms; an inlet nozzle located in the center of the first downstream bottom, a ring with a sharp inner inlet edge located in the center of the chamber on radial posts with the ability to move along the cylindrical chamber, and an outlet with a sharp edge located coaxially with the inlet nozzle in the center of the other bottom. The inlet nozzle is connected to the tubing channel, and the outlet is directed into the annulus of the well. Liquid is supplied through the inlet nozzle into the cylindrical chamber, directing the liquid jet into the outlet in such a way that the jet in the space between the inlet nozzle and the outlet hole flows through the ring and touches the sharp inner inlet edge of the ring with its disturbed periphery, while forming a liquid jet with a disturbed periphery in the space between the bottoms. Primary pressure oscillations are thus generated in the area of the sharp edge of the ring, which are amplified due to the fact that in the cylindrical chamber the frequency of natural oscillations is pre-tuned to resonance with the frequency of primary pressure oscillations, as a result, pressure waves are formed behind the outlet in the annulus of the well.

The disadvantages of the method and device selected as a prototype is the lack of modulation of the waves of primary pressure fluctuations. The device generates primary pressure oscillations of the same frequency, since there is only one generating hole with a sharp edge, the chamber is also configured to amplify only these oscillations.

The technical problem to be solved by the claimed group of inventions is not only the generation of primary vibrations, but also the modulation of waves that arise inside the chamber, amplify and propagate into the annulus. The technical problem is also the expansion of the arsenal of devices and methods for generating and modulating pressure waves in the annulus.

The technical result consists in generating primary oscillations at two high close frequencies, and this mode produces low-frequency beats, leading to modulation of the waves that arise inside the chamber, amplify and propagate into the annulus at the beat frequency. Also, the technical result provided by the invention is the implementation of the specified purpose by the invention.

The technical problem is solved, and the specified technical result is achieved by a device for generating pressure waves in the injection wellbore - a Helmholtz jet oscillator (JOG), consisting of:

a cylindrical chamber bounded by two parallel bottoms, with an inlet nozzle located in the center of the downstream bottom on the axis of the cylindrical chamber and connected to the tubing channel, with an outlet located in the center of the downstream bottom on the axis of the cylindrical chamber, directed into the annulus of the well , with a ring with a sharp inlet edge mounted coaxially to the inlet nozzle and outlet, in which inside the cylindrical chamber between the bottoms, on the axis of the cylindrical chamber behind the first, a second ring with a sharp inlet edge is installed, coaxial to the first ring, and the first ring with a large hole diameter is installed closer to the inlet nozzle, and the second ring with a smaller hole diameter is installed behind the first ring.

Also, the technical problem is solved, and the specified technical result is achieved by the claimed method of generating pressure waves in the injection wellbore, in which:

install at the lower end of the tubing (tubing) a device for generating pressure waves in the fluid flow - a Helmholtz jet oscillator (JOG), consisting of:

a cylindrical chamber bounded by two parallel bottoms, with an inlet nozzle located in the center of the downstream bottom on the axis of the cylindrical chamber and connected to the tubing channel, with an outlet located in the center of the downstream bottom on the axis of the cylindrical chamber and directed into the annulus of the discharge wells, a ring with a sharp inlet edge mounted coaxially with the inlet nozzle and the outlet on the axis of the cylindrical chamber between the bottoms;

liquid is fed through the inlet nozzle into the cylindrical chamber, the liquid jet is directed through the ring to the outlet, the liquid jet is formed with the perturbed periphery in the space between the bottoms, and primary pressure fluctuations are generated when the jet flows through the ring,

amplify the primary pressure fluctuations in the cylindrical chamber due to the excitation of resonance at the frequency of its own oscillations, which is tuned constructively during the production of the cylindrical chamber, form pressure waves behind the outlet in the annulus of the well,

primary pressure oscillations are generated in the cylindrical chamber at two high close frequencies, low-frequency beats are created and resonance is excited in the cylindrical chamber at a beat frequency that corresponds to the natural oscillation frequency of the cylindrical chamber, a low-frequency pressure wave is formed behind the outlet in the well annulus at the beat frequency.

A feature of the proposed method is that a Helmholtz jet oscillator is used, inside the cylindrical chamber of which between the bottoms, on the axis of the cylindrical chamber, at a small distance from the first, a second ring with a sharp leading edge is installed coaxially to the first ring, and the first ring with a large hole diameter is installed closer to the inlet nozzle, and the second ring with a smaller hole diameter is installed behind the first ring.

Unlike the prototype, where there is no modulation of waves inside the chamber, the generation of primary oscillations at two high close frequencies produces low-frequency beats, leading to modulation of the waves that arise inside the chamber, amplify and propagate into the annulus at the beat frequency.

The figure 1 shows a diagram of the proposed device (left longitudinal, right transverse sections).

The figure 2 shows an oscillogram with beats when the claimed device generates pressure fluctuations at two close frequencies.

The figure 3 shows the amplitude-frequency characteristic (AFC) of the oscillatory process in the proposed device in the beat mode.

The inventive device for generating and modulating pressure waves in the annulus of the well consists of a cylindrical chamber 1, which is a hollow steel pipe, muffled on both sides with flat steel bottoms. The bottoms of the chamber 1 are tightly welded to the steel pipe and installed parallel to each other.

In the upstream (inlet) bottom of the cylindrical chamber 1, on the axis of the chamber 1, an inlet nozzle 2 is installed, which is a small piece of steel pipe.

In the downstream (outlet) bottom of the cylindrical chamber 1, an outlet 3 is made with a sharp inner edge facing the inside of the cylindrical chamber 1.

Also in the cylindrical chamber 1, coaxially with the inlet nozzle 2 and outlet 3, two steel rings 4 and 5 are installed at a small distance from each other. Rings 4 and 5 can be installed in the cylindrical chamber 1 in any possible way, for example, as in the prototype, on radial posts welded to the chamber and to the rings.

Rings 4 and 5 have sharp inner inlet edges on the side facing the inlet nozzle. In this case, the ring 4, with a large hole diameter, is installed closer to the inlet nozzle 2, and the ring 5, with a smaller hole diameter, is structurally placed behind the ring 4. The holes of the rings are made of different diameters so that the inner hole gets into the ring 5 with a smaller diameter of the inner hole. the undisturbed part of the jet, and not a trace from the front ring. This was done to enable the generation of primary pressure oscillations at two close frequencies, determined by the distance of the ring from the inlet nozzle 2.

The dimensions of the holes of the rings do not affect the frequency of generation of primary oscillations, only the distances between the ring 4 and the inlet nozzle 2 and the ring 5 and the inlet nozzle 2 matter.

Operates a device for generating pressure waves in the annulus of the well as follows.

The proposed method is based on the use of the ability of a high-speed liquid jet to generate weak local pressure fluctuations when it impinges on an obstacle with a sharp (generating) edge. A sharp wedge, a hole with a sharp edge in a plate, or a ring installed coaxially with the jet can be used as a generating edge. When the jet impinges on the sharp edge of the ring, in the immediate vicinity of the impact point, weak primary pressure fluctuations (PSOs) arise. Their amplitude is very small, and they can be caught only with special tools, and the frequency of occurrence is determined by the expression of formula (1).

To form a wave field at the bottom of wells, a hydrodynamic generator of pressure fluctuations in the flowing fluid flow is installed at the lower end of the tubing. The most effective device is the Helmholtz jet oscillator (JOG), in which, before the device is placed in the tubing, the frequency of natural oscillations of the pressure of the cylindrical chamber is pre-tuned.

The frequency of generation of primary pressure fluctuations (POS) when the jet impinges on the sharp edges of the rings is determined from the formula:

(1),

(1),

where W is the jet velocity, L _STR is the jet length, Sh is the Strouhal number, which is determined experimentally (Sh≈0.3). The generation frequency is changed by adjusting the length of the free section of the jet, or the speed of the outflow from the inlet nozzle 2 when the supply pressure changes. The distance between the bottoms L _D is identical to the length of the jet L _CSR in the resonator without rings, and in this invention L ₁ and L ₂ are the distances between the exit edge of the inlet nozzle 2 and the rings 4 and 5, respectively. The flow rate of the supplied liquid and the pumping rate are determined by the injectivity of the formation and maintained unchanged during the workover on the well.

In the claimed method, it is possible to adjust the frequency of generation of primary pressure oscillations ω on the sharp inner inlet edge of the ring at a constant jet velocity W by moving the rings along the jet axis with a change in the jet length L _CTR . This allows you to change the volume ( V ) of the cylindrical chamber 1 to match the natural frequency of the cylindrical chamber 1 f _C with the frequency of the primary pressure oscillations at the sharp edge ω.

The frequency of natural oscillations (FFR) of the cylindrical chamber of the Helmholtz jet oscillator is determined by the Rayleigh formula,

(2)

(2)

where c is the speed of sound, S ₁ is the area of the passage section of the inlet nozzle, ℓ ₁ is the length of the inlet nozzle, S ₂ is the area of the passage section of the outlet, ℓ ₂ is the length of the outlet, V is the volume of a cylindrical chamber with a diameter D and a length L (distance between bottoms).

In the prototype, the size of the cylindrical chamber 1 is calculated in such a way that the frequency of natural oscillations of the liquid column contained in it is equal to the frequency of generation of primary pressure oscillations at the sharp edge of the outlet. Usually, the required frequency of generation of primary pressure fluctuations is known, this is the same value that is required by oilmen to clean up a well being repaired. If the frequency of formation of these pressure perturbations coincides with the frequency of natural oscillations of a stationary liquid column enclosed inside the cylindrical chamber 1, then the amplitude of pressure oscillations increases many times.

In the claimed invention, primary pressure fluctuations are generated on the sharp edges of the rings 4 and 5. On ring 4, PQDs of higher frequency (ω ₁ ) are generated, since it is installed closer to the inlet nozzle 2 and ℓ ₂ in the denominator of formula (1) is less, and on ring 5, PKDs of lower frequency (ω ₂ ), since it is installed at a larger distance from the inlet nozzle. Since the distances and ℓ ₁ and and ℓ ₂ between the outlet edge of the inlet nozzle 2 and rings 4 and 5 have similar values (rings 4 and 5 are located close to each other), the VCDs generated on the sharp edges of rings 4 and 5 have close frequencies ( ω ₁ and ω ₂ ), the oscillations of these two close frequencies ω ₁ and ω ₂ are amplified, and their interaction in a closed volume leads to periodic bursts of pressure with a frequency equal to (ω ₁ -ω ₂ ). When two periodic pressure oscillations of close frequencies ω ₁ and ω ₂ are superimposed in the cylindrical chamber 1, a beating mode occurs (Crawford F.M., Waves. Subject: Physics. University: KuzGTU. p. 42), as a result of which in the cylindrical chamber 1 there are pressure fluctuations with the main frequency ω=(ω ₁ +ω ₂ )/2, as well as with the beat frequency (ω ₁ -ω ₂ ).

In the claimed method, the size of the cylindrical chamber 1 is formed in such a way that the frequency of natural oscillations of the liquid column contained in it is equal to the beat frequency (ω ₁ -ω ₂ ).

The cylindrical chamber 1 is installed at the lower end of the tubing and its inlet nozzle 2 is connected to the tubing channel, and the outlet 3 is directed into the annulus of the well. When a technical fluid is supplied to the tubing of a well being repaired, all the supplied fluid flows through the inlet nozzle 2, and at the same time, an axisymmetric jet is formed at the outlet of the nozzle. The jet rushes to rings 4 and 5 with sharp inner edges facing the flow, while primary local pressure oscillations of two close frequencies are generated in the region of the sharp edges of ring 4 and ring 5, which creates an oscillatory system with a frequency of natural oscillations (FFR) excited at flow of a round jet of liquid onto the sharp edges of rings 4 and 5. Since rings 4 and 5 are removed from the exit edge of the inlet nozzle 2 by a different but close distance, the frequency of generation of the PSD on each of them will be slightly different, and the oscillations of these two close frequencies will be amplified, and their interaction in a closed volume will lead to periodic bursts of pressure with a frequency equal to the difference in frequencies generated on rings 4 and 5 (beat frequency), oscillations occur at the fundamental frequency, and at the beat frequency. The FSK of the cylindrical chamber 1 resonates with the beat frequency, multiplying the oscillation amplitude. Further, a powerful jet flows through the outlet 3 down the wellbore into the annulus into the productive formation and even further into the bottomhole formation zone, exerting an increased mechanical effect on solid deposits on the well walls, which contributes to their more efficient cleaning.

Figures 2 and 3 show the oscillogram and the amplitude-frequency spectrum (AFS) of the oscillatory process in the claimed device in the beat mode. In ASF, two dominant close frequencies are observed: 173 and 195 Hz.

Therefore, periodic bursts and dips in the amplitude of the recorded signal due to beats are visible in the oscillogram.

The proposed group of inventions - a method for generating and modulating pressure waves in an injection wellbore and a device for its implementation - allow the generation of primary pressure oscillations at two close frequencies, leading to wave modulation in the annulus, and thereby increase the efficiency of pressure oscillations, increase fluid mobility in the bottomhole formation space and increase the mechanical impact on solid deposits on the walls of the well when pumping technical fluid into it through a jet parametric emitter due to the formation of a high-amplitude low-frequency pressure wave in the well channel, as well as expand the arsenal of devices and methods for generating and modulating waves pressure in the annulus.

The study was supported by the Russian Science Foundation grant No. 22-29-01174, https://rscf.ru/project/22-29-01174/.

Claims (8)

1. A method for generating pressure waves in an injection wellbore, in which a device is installed at the lower end of the tubing (tubing) for generating pressure waves in a fluid flow - a Helmholtz jet oscillator, consisting of: a cylindrical chamber bounded by two parallel bottoms, with an inlet nozzle located in the center of the downstream bottom on the axis of the cylindrical chamber and connected to the tubing channel, with an outlet located in the center of the downstream bottom on the axis of the cylindrical chamber and directed into the annulus of the injection well, a ring with a sharp inlet edge mounted coaxially with the inlet nozzle and the outlet on the axis of the cylindrical chamber between the bottoms; liquid is fed through the inlet nozzle into the cylindrical chamber, the liquid jet is directed through the ring to the outlet, the liquid jet is formed with the perturbed periphery in the space between the bottoms, and primary pressure fluctuations are generated when the jet flows through the ring, amplify the primary pressure fluctuations in the cylindrical chamber due to the excitation of resonance at the frequency of its own oscillations, which is tuned constructively during the production of the cylindrical chamber, form pressure waves behind the outlet in the annulus of the well, characterized in that a Helmholtz jet oscillator is used, inside the cylindrical chamber of which, between the bottoms, on the axis of the cylindrical chamber behind the first, a second ring with a sharp input edge is installed coaxially to the first ring, the first ring with a large hole diameter is installed closer to the inlet nozzle, and the second ring with a smaller hole diameter is installed behind the first ring, primary pressure oscillations are generated in the cylindrical chamber at two high close frequencies, low-frequency beats are created and resonance is excited in the cylindrical chamber at a beat frequency that corresponds to the natural oscillation frequency of the cylindrical chamber, a low-frequency pressure wave is formed behind the outlet in the annulus well space at the beat frequency. 2. A device for generating pressure waves in a liquid flow - a Helmholtz jet oscillator, consisting of: a cylindrical chamber bounded by two parallel bottoms, with an inlet nozzle located in the center of the downstream bottom on the axis of the cylindrical chamber and connected to the tubing channel, with an outlet located in the center of the downstream bottom on the axis of the cylindrical chamber, directed to well annulus, with a ring with a sharp inlet edge, installed coaxially with the inlet nozzle and the outlet on the axis of the cylindrical chamber between the bottoms, characterized in that inside the cylindrical chamber between the bottoms, on the axis of the cylindrical chamber behind the first, a second ring with a sharp inlet edge is installed coaxially to the first ring, and the first ring with a large hole diameter is installed closer to the inlet nozzle, and the second ring with a smaller hole diameter is installed behind the first ring.

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