RU2670623C9 - Method and device of borehole acoustic radiator with a smooth nozzle input for generating waves of pressure in annulus of injection well - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: group of inventions refers to the oil industry and is intended for cleaning from solid deposits of casing walls and perforation holes, decolmatation of the bottomhole formation zone and increasing mobility of formation fluids. Borehole acoustic radiator for generating pressure waves in a liquid flow is a hollow body of revolution and consists of: cylindrical chamber with two flat covers; axially symmetric nozzle formed in the center of the front cover and an outlet with a sharp edge made coaxially with a nozzle in the center of the rear cover. Moreover, the nozzle includes a tapering accelerating portion and a cylindrical alignment portion terminating in a plane nozzle cut orthogonal to the axis of the nozzle. At the same time, the geometry of the tapering acceleration section is smoothly coupled to the geometry of the cylindrical aligning section without kink of the contour of the nozzle. In this case, the flat nozzle section is located on the inner wall of the front cover.EFFECT: technical result is an increase in the amplitude of pressure oscillations in the annulus of the injection well.2 cl, 6 dwg

Description

The invention relates to the oil industry and is intended for cleaning from solid deposits of casing walls and perforations, decolmatization of the bottomhole formation zone and increasing the mobility of formation fluids.

A known method of generating pressure waves in the injection wellbore (see patent No. 96118034), in which a hydrodynamic generator (GG) is installed at the end of the tubing, compressible fluid is pumped through the tubing, compressible fluid is pumped through the GG, pressure fluctuations are generated inside the GG and form pressure waves behind the GG in the injection well bore and then in the annulus of the injection well ..

Oil production wells are periodically cleaned from solid deposits on the walls and in the perforation holes of the casing, pumping various technical compressible fluids (gas, air, steam). It was noted that the presence of pressure fluctuations in the pumped gas helps to achieve a better result.

The most effective methods of creating pressure fluctuations in the well bore with the help of GGs installed directly in the place where they are most in demand, i.e. at the lower end of the tubing. With this method of generating pressure fluctuations, all gas is pumped through the GG, which creates pressure fluctuations in the gas flowing through it, spreading its effect on the adjacent area.

In the GG there are no moving parts. GG is a device in which part of the kinetic energy of the pumped liquid (gas) flow is converted into vibrational energy using a special channel shape.

The disadvantage of GH is that only a small fraction of the kinetic energy of the stream is converted into vibrational energy.

A known method of generating pressure waves in the injection wellbore, implemented in the device (see Morel Th. Experimental study of a Helmholtz oscillator controlled by a jet. Translation of the WCP No. B-56251 from J. Fluid Engineering, 1979, 101, IX, No. 3, 383- 390, attached to the disk) closest in technical essence and taken as a prototype, in which a downhole acoustic emitter is installed on the lower end of the tubing (tubing), consisting of: a resonator chamber with two covers; a nozzle located in the front cover and an outlet with a sharp edge located coaxially with the nozzle in the rear cover; in which the nozzle is connected to the tubing, and the outlet is directed into the annulus of the well, moreover, the nozzle includes a booster section and a leveling section ending with a nozzle section, while supplying liquid through the tubing to the nozzle, increasing the fluid flow rate in the booster section and creating leveling section of the liquid stream with reduced static pressure, form a free liquid stream behind the nozzle cut, which is directed to the sharp edge of the outlet, generate primary pressure fluctuations in areas of the sharp edge reinforce these primary pressure oscillations in the resonator chamber, the natural oscillation frequency of which is tuned in resonance with the frequency of the primary pressure oscillation generation, and create pressure waves behind the outlet in the annulus of the well

Hydrodynamic generators of pressure fluctuations in the fluid flow are structurally different, but, as a rule, they include two main parts: a jet generator (SG) and a cavity resonator chamber (CCF), which function relatively independently. SG is designed to convert some part of the kinetic energy of the jet into the energy of the primary oscillations of the flow. COR is designed to increase the amplitude of the primary pressure fluctuations. To amplify the primary pressure oscillations, it is necessary to coordinate the frequency of their generation with the frequency of natural oscillations of the BOR. In other words, two parts of the same device must be tuned in unison to achieve resonance.

The most effective device for converting the energy of the high-pressure head of the jet into the vibrational energy of the flow is the Helmholtz resonator (AWG in the translation of the article taken as a prototype), which we call the jet acoustic emitter (SAI).

The process of generating pressure oscillations in the IG stream begins with acceleration, since the amplitude of pressure oscillations A increases with the magnitude of the velocity head A ~ ρυ ² / 2strui. The acceleration of the flow is carried out in the inlet nozzle, which, in addition to increasing the speed, also serves to form a round jet. The formed free stream is directed through the entire cavity chamber directly into the outlet and touches its sharp inner edge with its perturbed periphery. This gives rise to small local pressure disturbances in the region of the sharp edge. The resonator serves to amplify these primary pressure fluctuations.

When flowing into the nozzle, the flow narrows and accelerates, and the pressure inside it decreases, in accordance with Bernoulli's law. In this case, the flow inside the nozzle occupies only a part of the bore. But during the flow inside the nozzle, the flow gradually expands, and if the length of the nozzle is sufficient, then at the exit from the nozzle, the flow expands so much that it occupies the entire area of the nozzle exit. If the nozzle length is insufficient, then the flow occupies only the central part of the nozzle cut, and along the nozzle wall, outside the jet, liquid from the resonator chamber will begin to be sucked into the nozzle, since the pressure there is lower than in the chamber.

This liquid moves inside the nozzle along the wall towards the flow in the form of a thin film surrounding a round stream from all sides, and then it is picked up by the stream and carried out. This sluggish film enveloping a free stream of liquid at the exit of the nozzle reduces the intensity of the interaction of the jet with the sharp edge of the outlet, resulting in a noticeable weakening of the generation of primary pressure oscillations in the region of the output sharp edge and a decrease in the amplitude of pressure fluctuations at the exit of the device.

The disadvantage of this method, taken as a prototype, is the low intensity of the interaction of the jet with the sharp edge of the outlet.

A device is known for generating pressure fluctuations in a fluid stream (see US Pat. No. 6,029,746), which is a hollow body of revolution and consisting of: a cylindrical chamber with two covers; a cylindrical nozzle made in the center of the front cover and an outlet with a sharp edge located coaxially with the nozzle in the center of the back cover; moreover, the cylindrical nozzle ends with a flat nozzle cut orthogonal to the axis of the nozzle and located on the inner wall of the front cover of the chamber.

The device consists of two relatively independent elements. The inlet nozzle, the outlet, and the gas stream flowing between them form a jet generator (SG) of primary pressure oscillations, which also functions in the absence of a cavity resonator chamber (CBS), although the amplitude of the primary pressure oscillations generated by it is very small. But if you install SG inside a tuned CDF, then the amplitude of the primary pressure fluctuations will increase many times.

The resonator is passive, it only responds, i.e. amplifies the pressure fluctuations created by some other device, because the gas column enclosed in it is almost motionless. The generator is active, it itself creates the primary pressure fluctuations, since it contains a high-speed jet, which has a kinetic energy reserve for this.

The device is equipped with a cylindrical nozzle, which is a through hole in a flat cap. The input section, as such, is absent. The nozzle begins with a sharp inlet edge and ends with a sharp outlet edge. In a cylindrical channel, the jet is strongly compressed, enveloping the input sharp edge, and fills the channel section by 70% (Idelchik I.E. Handbook of hydraulic resistances. M .: Mechanical Engineering. 1992).

The disadvantage of this device is the lack of a tapering inlet portion of the nozzle.

A device for generating pressure fluctuations in a fluid stream (see patent US 4041984), consisting of a cylindrical chamber with two covers; an axisymmetric tapering nozzle mounted in the center of the front cover and an outlet with a sharp edge located coaxially with the nozzle in the center of the back cover; moreover, the nozzle ends with a flat nozzle cut orthogonal to the axis of the nozzle.

This device includes the same basic elements as the device described above, namely, it is a jet generator installed in the chamber of the cavity resonator. The nozzle has a tapering inlet section, providing a smooth increase in the fluid velocity without separation of the flow from the walls and the nozzle is completely filled with the fluid flow in the leveling section. The flow also completely fills the nozzle cut area, leaving no possibility for the liquid from the chamber to flow into the nozzle along the annular gap between the jet and the nozzle wall.

A nozzle with a flat cut orthogonal to the axis of the nozzle is significantly recessed into the cylindrical chamber. With this arrangement of the nozzle cut, the length of the free portion of the jet between the nozzle cut and the sharp edge of the outlet is less than the length of the chamber.

The outer wall of the nozzle gradually thins (disappears), and the nozzle has a sharp annular edge, similar to a knife blade, in the plane of the nozzle cut. Due to the absence of a flat end at the exit of the nozzle, an annular vortex is not formed in the plane of the nozzle cut, generating instability at the periphery of the jet and determining the generation of primary pressure oscillations at the sharp edge of the outlet.

The disadvantage of this device is the recessing of the nozzle deep into the chamber and the location of the flat nozzle cut not on the flat inner wall of the front cover, but in the depth of the chamber.

A device is known for generating waves in a fluid flow, the closest in technical essence and taken as a prototype, (see Morel Th. Experimental study of a Helmholtz oscillator controlled by a jet. Translation of digital-electronic converter No. B-56251 from J. Fluid Engineering, 1979, 101, IX No. 3, 383-390, attached to the disk), which is a hollow body of revolution and consisting of: a cylindrical chamber with two flat covers; an axisymmetric nozzle made in the center of the front cover and an outlet with a sharp edge, made coaxially with the nozzle in the center of the back cover; moreover, the nozzle includes a tapering section and a cylindrical section ending in a flat nozzle section orthogonal to the axis of the nozzle.

Schematically, the device is shown in figure 1. The device is a cylindrical chamber with two flat covers. In the center of the front cover is a nozzle of cylindrical shape, which is connected to the supply line of the working fluid. In the center of the back cover, coaxial to the nozzle, there is a cylindrical outlet with a sharp inlet edge. The diameter of the outlet is approximately 1.3 nozzle diameters. The length of the chamber is equal to the interval between the front and rear covers and corresponds to the length of the jet that flows inside the chamber between the nozzle and the outlet.

The nozzle is a drilling in a flat cap and has sharp edges on both sides. The inlet portion of such a nozzle represents a sharp transition from a larger diameter to a smaller one, since the inner diameter of the pipe to which the nozzle is connected substantially exceeds the diameter of the nozzle. The nozzle is cut off by a plane orthogonal to the axis of the nozzle and representing the inner wall of the front cover. The nozzle exit faces the inside of the chamber, the diameter of which significantly exceeds the diameter of the nozzle.

The disadvantage of this device is the lack of a smooth inlet area at the nozzle.

The aim of the present invention is: the creation of AIS with a profiled nozzle, which provides a tapering inlet section, and the cylindrical section ends with a flat nozzle section located on the inner wall of the front cover of the camera.

The technical result is achieved due to the fact that the method of generating pressure waves in the annulus of the injection well, in which a downhole acoustic emitter is installed at the lower end of the tubing (tubing), consisting of: a resonator chamber with two covers; a nozzle located in the front cover and an outlet with a sharp edge located coaxially with the nozzle in the rear cover; in which the nozzle is connected to the tubing, and the outlet is directed into the annulus of the well, moreover, the nozzle includes a booster section and a leveling section ending with a nozzle section, while supplying liquid through the tubing to the nozzle, increasing the fluid flow rate in the booster section and creating leveling section of the liquid stream with reduced static pressure, form a free liquid stream behind the nozzle cut, which is directed to the sharp edge of the outlet, generate primary pressure fluctuations in the areas of the sharp edge reinforce these primary pressure oscillations in the resonator chamber, the natural oscillation frequency of which is tuned in resonance with the frequency of the primary pressure oscillation generation, and create pressure waves behind the outlet in the annulus of the borehole, provide a smooth increase in the fluid velocity at the acceleration section of the nozzle without separation of the flow from the walls and without preloading the jet in the leveling section, uniformly fill the nozzle in the leveling section and form a rectangular velocity plot on the nozzle with cut, exclude liquid suction along the edge of the nozzle cut from the resonator chamber into the nozzle along the wall of the leveling section, prevent the formation of a thick sluggish film on the periphery of the jet behind the nozzle cut, and intensify the interaction of the jet with the sharp edge of the outlet.

In a device for generating pressure waves in a fluid stream, which is a hollow body of revolution and consisting of: a cylindrical chamber with two flat covers; an axisymmetric nozzle made in the center of the front cover and an outlet with a sharp edge, made coaxially with the nozzle in the center of the back cover; moreover, the nozzle includes a tapering section and a cylindrical section ending with a flat nozzle section orthogonal to the axis of the nozzle, the geometry of the tapering section smoothly matches the geometry of the cylindrical section without breaking the nozzle contour, and a flat nozzle section is located on the inner wall of the front cover.

The proposed method allows only by profiling the inlet portion of the nozzle made in the front cover so that the nozzle section is located on the inner wall of the front cover to increase the amplitude of pressure fluctuations in the annulus of the injection well three or more times.

In figure 1. presents a diagram of the camera jet acoustic emitter with a cylindrical nozzle.

Figure 2 presents a diagram of the camera jet acoustic emitter with a profiled nozzle having a tapering inlet section, smoothly mating with a cylindrical section ending in a flat nozzle section.

Figure 3 presents a schematic representation of the jet in the cylindrical channel of the nozzle and in the free section and its characteristic dimensions.

Figure 4 presents a schematic representation of the jet in the profiled channel of the nozzle and in the free section and its characteristic dimensions.

Figure 5 shows the jet filling the channel of the cylindrical nozzle. Also shown is the return flow inside the nozzle along the channel wall, fragments of which are carried away by the jet to the outlet.

Figure 6 shows the jet filling the channel of the profiled nozzle. Also depicted are fragments of a vortex ring carried by a jet to an outlet.

The essence of the proposed invention is as follows.

The nozzle, as you know, is a narrowing of the channel and serves to increase the flow rate, and the flow rate at the exit of the profiled nozzle (see figure 2), having a smooth narrowing at the inlet, differs very slightly from the flow rate at the exit of a simple nozzle ( see figure 1) having a cylindrical shape. The velocity coefficient ϕ, which is the ratio of the true velocity to the theoretical one, is of the order of 0.97 for nozzles that differ significantly geometrically (see I. Idelchik, Handbook of Hydraulic Resistances. M.: Mechanical Engineering. 1992).

Moreover, the experiments with nozzles of various shapes show that the amplitude of pressure fluctuations in the cavity chamber with a profiled nozzle can be three times higher than with a cylindrical nozzle. The profiled nozzle, as well as the non-profiled one, had a cylindrical section equal to the diameter of the nozzle, and was distinguished by the presence of a smoothly tapering inlet section. The shape of the tapering section provided an uninterrupted flow of air, both in the tapering section itself and in the cylindrical section. It is known that nozzles shaped in this way have a uniform velocity profile at the output (Artemyeva T.V., Lysenko T.M., Rumyantseva A.N., Stesin S.P. Hydraulics, hydraulic machines and hydropneumatic actuators. M .: Publishing Center “Academy". 2005).

In a cylindrical nozzle installed in the supply line, which is a pipe of a larger diameter, the flow is significantly compressed when turning around the input sharp edge and detaches from the wall of the cylindrical section of the nozzle (see Fig. 3). The static pressure in the stream (hereinafter simply pressure) decreases significantly with increasing speed. The stream fills approximately 70% of the nozzle cross-sectional area, and the pressure inside the nozzle channel approximately corresponds to the pressure in the stream. The nozzle cut area is occupied by the flow by only 70% in the center, and in the annular gap between the nozzle wall and the flow there is no directional movement. For this reason, air from the chamber rushes into the nozzle along the wall along the annular gap, since there the pressure is lower than the pressure in the resonator chamber, forming a reverse flow near the nozzle channel wall (see Fig. 5). The reverse flow extends its influence almost to the inlet sharp edge of the nozzle, and the liquid from the resonator chamber moves along the wall almost to the inlet edge of the nozzle, and then it is picked up by the flow and carried out of the nozzle into the chamber.

The authors propose to eliminate the flow of fluid from the cavity chamber into the nozzle. For this, it is necessary to organize the fluid flow in the inlet section of the nozzle in such a way that there is no flow separation from the nozzle wall during its acceleration and rotation before flowing into the cylindrical section. It is necessary to arrange the acceleration of the liquid and the rotation of the flow at the inlet so that the nozzle exit area of the nozzle is completely filled with the flow, and the velocity plot at the nozzle exit has a uniform rectangular profile (see Fig. 4).

In this case, the nozzle cut should be located on the inner surface of the front cover of the camera. The nozzle cut must be flat. The plane of the nozzle cut should be orthogonal to the axis of the nozzle and should be aligned with the plane of the inner wall of the front cover of the chamber. At the exit of the nozzle, behind the exit with a sharp edge of 90 °, it is necessary to organize an annular vortex in the stagnant zone.

The mechanism for generating pressure fluctuations in the generally accepted form is described in the materials of the article, from which the prototypes of both the method and the device are taken. It consists in the formation by the jet of a vortex ring behind the outlet edge of the nozzle, from which the vortex fragments are strictly periodically torn off and carried away by the stream onto the sharp edge of the outlet. Hitting a sharp edge, these vortex fragments are deformed, as a result of which in the resonator chamber, in the local region near the edge, weak primary pressure oscillations arise. The natural frequency of the resonator chamber corresponds to the frequency of generation of the primary pressure oscillations; as a result, the resonance mode sets in - the amplitude of the pressure oscillations in the chamber increases many times.

Figure 5 conditionally shows a picture of the flow in the nozzle of a device taken as a prototype — it can be seen that vortex formation begins deep inside the nozzle, near the inlet sharp edge of the nozzle and gradually occupies the entire thickness of the stream. The dashed line shows the unperturbed core of the flow, which is gradually eroded. A jet flows from such a nozzle surrounded by a thick vortex sluggish film, which prevents the interaction of the jet itself with a sharp edge.

Figure 6 shows the flow pattern in a profiled nozzle with a smooth entry - it is clear that the nozzle section is completely filled with a liquid jet, there is no liquid suction inside the nozzle, nothing prevents the jet from interacting with both the annular vortex at the nozzle exit and the sharp edge of the outlet . Vortex fragments with high speed are carried away by the jet to a sharp edge and are intensively deformed, forming primary pressure fluctuations of a more substantial amplitude than in the first case. The intensity of pressure fluctuations in the cavity chamber increases significantly.

A device for generating pressure waves in the annulus of an injection well (see FIG. 2) consists of a cylindrical body 1, a front flat cover 2, a rear flat cover 3, a profiled nozzle with a smooth inlet 4 in the front cover, an outlet with a sharp edge 5 in back cover. The chamber of the cavity resonator is a tube plugged at both ends with flat caps mounted parallel to each other and perpendicular to the axis of the cavity chamber. An inlet nozzle is made in the first (downstream) chamber lid, and an outlet is made in the rear lid.

The nozzle has an accelerating tapering section, the profile of which is a section of an arc of a circle with a radius of at least four diameters of the cylindrical section of the nozzle. The narrowing section can be performed in a more complex way, for example, profiled along the Vitoshinsky curve or Bernoulli's lemniscate. In these cases, the tapering acceleration section mates with the cylindrical leveling section without breaking the profile of the contour, and the flow moves in the nozzle without separation from the wall. The cylindrical section of the nozzle ends with a flat nozzle cut with a sharp exit edge of 90 °. The plane in which the nozzle section is made is orthogonal to the axis of the nozzle and aligned with the inner flat wall of the front cover, in which the nozzle is made.

The outlet in the rear cover is aligned with the nozzle and has a sharp edge of 90 ° directed towards the nozzle.

The device is installed on the lower end of the tubing and its nozzle is connected to the tubing channel, and the outlet is directed down along the perforation of the well.

A device for generating pressure waves in the annulus of a well operates as follows. When a technical compressible fluid is supplied to the tubing of a well being repaired, all the supplied fluid flows through the borehole acoustic emitter. At the same time, a circular stream of liquid is formed at the exit from the nozzle, which rushes into the outlet, touches the sharp edge with its perturbed periphery, and weak primary pressure oscillations are generated with strict periodicity in the region of the sharp edge. Since the frequency of generation of the primary pressure oscillations corresponds to the frequency of natural oscillations of the pressure of the cavity chamber, their amplitude increases many times, and a pressure wave forms behind the outlet. Further, the wave propagates through the perforation holes into the annulus.

A distinctive feature of the operation of this device is that when the flow rate in the profiled nozzle increases, the flow does not detach from the walls of the nozzle inlet section, due to the fact that the inlet section profile provides an uninterrupted mode of fluid flow and smoothly mates with the leveling section. In the general case, a leveling cylindrical section may not be necessary, since a stream with a rectangular velocity profile already exits from the accelerating tapering section.

The stream fills the entire area of the nozzle exit at the exit from the cylindrical section. And, although the static pressure inside the cylindrical section of the nozzle is lower than the pressure in the resonator chamber and corresponds to the pressure in the jet in this section, liquid does not flow from the resonator chamber into the nozzle, since the jet fills the entire nozzle section and carries the adjacent fluid beyond the sharp nozzle cut edge. With this regime of jet outflow from the nozzle, it is considered that the boundary layer is absent at the section. The thickness of the boundary layer of the jet is calculated starting from the nozzle exit, and increases with distance from it. The periphery of the jet in a free section moves very energetically, and intensively interacts with the sharp edge of the outlet, generating periodic disturbances of high amplitude. These primary perturbations are amplified by the resonator chamber and form an elastic wave at the outlet of the device, propagating through the annulus through the perforation holes to the outside.

Claims (2)

1. A method of generating pressure waves in the annulus of an injection well, in which a downhole acoustic emitter is installed at the lower end of the tubing (tubing), consisting of: a resonator chamber with two covers; a nozzle located in the front cover and an outlet with a sharp edge located coaxially with the nozzle in the rear cover; in which the nozzle is connected to the tubing, and the outlet is directed into the annulus of the well, and the nozzle includes a tapering booster section and a cylindrical leveling section ending with a nozzle section, while supplying liquid through the tubing to the nozzle, increasing the fluid flow rate at the tapering booster section and creating in a cylindrical leveling section, a liquid stream with reduced static pressure forms a free liquid stream behind the nozzle section, which is directed to the sharp edge of the outlet versts, generate primary pressure fluctuations in the region of the sharp edge, amplify these primary pressure fluctuations in the resonator chamber, the natural frequency of which is tuned in resonance with the frequency of the primary pressure oscillations, and create pressure waves behind the outlet in the annulus of the well, characterized in that provide a smooth increase in the fluid velocity on the narrowing accelerating section of the nozzle without separation of the flow from the walls and without preloading the jet in the cylindrical leveling section, is Roughly fill the nozzle in a cylindrical leveling section and form a rectangular velocity plot on the nozzle section, exclude liquid sucking along the edge of the nozzle section from the resonator chamber into the nozzle along the wall of the cylindrical leveling section, prevent the formation of a thick sluggish film on the periphery of the stream behind the nozzle section, and intensify the interaction of the stream with a sharp edge of the outlet. 2. A downhole acoustic emitter for generating pressure waves in a fluid stream, which is a hollow body of revolution and consisting of: a cylindrical chamber with two flat covers; an axisymmetric nozzle made in the center of the front cover and an outlet with a sharp edge, made coaxially with the nozzle in the center of the back cover; moreover, the nozzle includes a tapering acceleration section and a cylindrical alignment section ending with a flat nozzle section orthogonal to the axis of the nozzle, characterized in that the geometry of the tapering acceleration section is smoothly coupled to the geometry of the cylindrical alignment section without breaking the nozzle contour, and a flat nozzle section is located on the inner wall of the front cover .

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