RU2371568C1 - Downhole device for prevention of fallout of deposits from flow of mined oil-bearing products, method of its manufacturing and operation - Google Patents

Abstract

FIELD: oil-and-gas production.

SUBSTANCE: device contains casing, implemented with ability of embedding into strip of oil-well tubing, installed in casing package of oscillations creation implemented with ability of action upon flow of mined products under action of mentioned flow. Package of oscillations creation is implemented in the form of packages of involution and scoring of flow. Package of involution corresponds cavity, limited by tapered surface of casing with tangential inlet and with located lengthwise its longitudinal axis rod-shaped turbolator, rigidly fixed by one end. Scoring package includes communicated hydraulically to cavity of involution package cylindrical chamber, open on outlet, with located lengthwise its longitudinal axis by free end of rod-shaped turbolator, outfitted by additional regulated turbolator. After assemblage of the device it is implemented setting of its package of oscillations creation to resonant behavior by changing of the position of additional regulated turbolator lengthwise free end of rod-shaped turbolator and flushing of fluid flow at bed with frequency characterisation.

EFFECT: design simplification and effectiveness increase of cleaning.

14 cl, 6 dwg

Description

The proposal relates to the field of hydrocarbon production and can be used in the conditions of operation of the well, when there is precipitation from the flow of produced products, for example, to combat waxing.

Known methods for changing the physicochemical properties of product streams by transferring liquid energy to vibrational processes.

The disadvantages of the known methods include the difficulty of achieving a sufficient radiation density of the product with the necessary process performance.

A known method of heat and mass energy exchange and a device for its implementation (RU 2268772, 2006), in which, in addition to the resonant excitation of the device structure, the cavitation process is excited by the contact of two or more vortex flows.

It is known that temporary (with subsequent restoration of the initial state) destruction of hydrocarbon molecules of the homologous series of composition C _n H _{2n + 2} to lighter molecules is observed at an irradiation density of up to 10 W / cm ² and irrevocable destruction at a density of more than 10 W / cm ² therefore, changing the physicochemical properties with the help of well-known cavitators is ineffective for solving industrial problems, since they exhibit a low radiation density (on average less than 5 W / cm ² ). Ultrasound affects the change in the viscosity of the product, breaks the continuous chain, breaking the bonds between the individual parts of the molecules. The creation of a turbulent flow (flow turbulization) by contact of the vortices is achieved by a rather complicated mechanical design of the device with impossible or complicated adjustment of the contact value of the vortices. As a result, most of the interaction energy of the vortices is consumed in the initial contact region of the flows with a rapid decrease in the vortex process with uniform geometry of the contact region. The inability to achieve the required radiation density in the given frequency ranges with the required device performance leads to a limited possibility of using the method for efficient heat and mass energy exchange processes.

The device cannot be used in borehole conditions to prevent the deposition of deposits from the flow of oil-containing products.

A well-known device for preventing the deposition of deposits from the flow of extracted oil-containing products, comprising a housing configured to be embedded in the tubing string, and an oscillation unit installed in the housing, configured to impact the flow of extracted oil-containing products under the influence of energy said stream (RU 2287665, 2006). The known device creates a pulsation of fluid in the tubing and is intended to clean the tubing from paraffin deposits during the extraction of oil-containing liquids (oil) in a fountain way or ESP units. This known device is the closest to the proposed combination of features and is taken as the closest analogue.

The disadvantages of the known device are: the complex structural design of the node creating oscillations - the presence of a large number of moving parts, which reduces the reliability of its operation; the possibility of inclusion in the work only in the presence of already deposited paraffin, therefore, the passage section of the tubing is narrowed, i.e. the device does not solve the problem of preventing deposits; the inability to temporarily or irrevocably change the molecular composition of hydrocarbons to lighter molecules by creating a vortex flow with high kinetic energy and resonant excitation.

There is a method of preventing paraffin deposits in tubing (RU 2105133, 1998), according to which an ultrasonic transducer is installed in a well, vibroactive oil processing is performed, while an ultrasonic transducer is installed in the zone of the beginning of intensive crystallization of paraffin, and vibroactive oil treatment is carried out in the cavitation mode for the level of the limit of cavitation strength of paraffin crystals and they are dispersed to sizes that exclude the possibility of subsequent coagulation.

The disadvantage of this method is the need for additional energy to power the ultrasonic transducer, which complicates the implementation of the method.

A known method of removing paraffin deposits from the walls of the tubing (RU 2106480, 1998), in which an ultrasonic transducer is installed in the well. Excite vibrations. An ultrasonic transducer is installed in the zone of the greatest thicknesses of paraffin deposits. The natural frequency of the radially and radially bending vibration modes of the tubing filled with oil with paraffin deposits is determined. The resonance oscillations at these frequencies excite in the NTC. The intensity of the vibration processing is maintained until the paraffin deposits are peeled off and dissolved in oil.

A disadvantage of the known method is the need to supply additional energy to power the ultrasonic transducer, which complicates the implementation of the method.

Also known is disclosed in the description of the invention (RU 2287665, 2006), in fact, a method of manufacturing and operating a downhole device, comprising manufacturing parts and assembly units of a downhole device, assembling and putting into operation, and putting into operation of the downhole device is carried out by embedding it in a column Well tubing in the area before the start of the zone of deposition of sediments from the flow of extracted oil-containing products.

The disadvantages of this method are the lack of the ability to prevent the deposition of deposits from the stream of extracted oil-containing products, the inability to adjust its oscillating circuit to the resonant mode of operation in the manufacture and subsequent operation of the device.

The technical result of the proposal is to simplify the design - there are no moving parts, as well as the possibility of influencing the flow of extracted oil-containing products under the action of the energy of the mentioned stream in an operating mode that provides a change in the physicochemical composition of oil-containing products, which contain paraffins, resins, and other components which leads to disruption of their molecular bonds, prevents deposits from falling out of the stream, and therefore they are easily brought to the surface with the stream.

A group of inventions, united by a single inventive concept, is proposed - a downhole device for preventing deposits from falling from a stream of extracted oil-containing products, a method for its manufacture and operation.

The technical result in the object of the invention is a downhole device to prevent deposits from falling from the stream of oil-containing products obtained by the fact that it contains a housing configured to be embedded in the tubing string, an oscillation unit mounted in the housing configured to withstand to the flow of extracted oil-containing products under the action of the energy of the said stream, while the oscillation generating unit is made in the form of twisting and sounding units flow, and the flow swirling unit is a cavity bounded by the conical surface of the housing with a tangential inlet and with a rod turbulator located along its longitudinal axis, rigidly fixed at one end, and the flow sounding unit is a cylindrical chamber hydraulically communicated with the cavity of the flow swirling unit, open at the outlet , with the free end of the rod turbulator located along its longitudinal axis, equipped with an additional adjustable turbulator.

In a specific example, an additional adjustable turbulator is mounted for movement and fixation along the free end of the rod turbulator using a threaded connection.

It is advisable that the diameter of the rod turbulizer located in the cavity of the flow swirling unit exceed the diameter of its free end located in the cylindrical chamber of the flow sounding unit, and the section connecting the different diameters of the rod turbulizer is made conical.

Turbulence of the flow increases if longitudinal grooves are made in the section of the rod turbulizer located in the cavity of the flow swirl unit, and longitudinal grooves are made in the conical section connecting different diameters of the rod turbulator, which are a continuation of the grooves made in the section of the rod turbulator located in the cavity knot twisting flow.

The device can be equipped with a tapered sleeve mounted on the conical surface of the body of the flow swirl assembly with radial through longitudinal slots hydraulically communicated with the tangential inlet and with the cavity of the flow swirl assembly.

In a specific example, the conical surface of the body of the flow swirling unit can be made in two stages, the first step having the shape of a truncated cone, and a conical sleeve with radial longitudinal slots communicating hydraulically with the tangential inlet and with the cavity of the flow swirling unit is installed in it.

Optimally, when the radial longitudinal slots of the conical sleeve are located opposite the longitudinal grooves of the core turbulator.

The technical result in the object of the invention is a method of manufacturing and operating a borehole device, made in accordance with this proposal, is achieved by the manufacture of parts and assembly units of the borehole device, its assembly and commissioning, while after assembly of the borehole device, its assembly is configured creating oscillations in the resonant mode of operation by changing the position of the additional adjustable turbulator and pumping the fluid flow on the stand with the removal of the frequency characteristics.

In this particular device, the position of the additional adjustable turbulator is carried out along the free end of the rod turbulator, trying to tune the oscillation unit to the resonant mode of operation of the downhole device, mainly in the frequency response region of 20,000-25,000 Hz.

Preferably, the commissioning of the downhole device is carried out by embedding it in the tubing string of the well in the area before the start of the zone of deposition of sediments from the stream of oil-containing products.

In the process of operating the downhole device, periodically after lifting it to the surface, its vibration generating unit is tuned to the resonant mode of operation in a similar manner.

The proposed group of inventions is illustrated by graphic images, in which figure 1 shows the downhole device, a longitudinal section; figure 2 is a bottom view of figure 1; figure 3 is a section aa in figure 1; figure 4 is a section bB in figure 1; figure 5 is an example of tuning on the stand of the frequency response of the device in the process of its manufacture; figure 6 is an example of putting the device into operation in a well equipped with a submersible pump.

The downhole device comprises a housing 1 configured to be embedded in a tubing string (tubing) 2, which is achieved by the presence of corresponding external threads at its ends. In the housing 1 is installed a hydraulic unit for generating oscillations, configured to affect the flow of extracted oil-containing products under the influence of the energy of the stream. The oscillation creation unit is made in the form of swirling and sounding nodes of the flow. The flow swirling unit is a cavity 3 bounded by the conical surface of the housing 1 with a tangential inlet 4 and with a rod turbulator 5 located along its longitudinal axis.

The conical surface of the housing 1 of the flow swirling unit can be performed in two stages, the first step having the shape of a truncated cone, and a conical sleeve 6 is installed in it with radial through longitudinal slots 7, hydraulically connected with the tangential inlet 4 and with a cavity 3 of the flow swirling unit.

The tangential inlet 4 is located in the nut 8 and technologically redesigned with the help of a ring 9 installed between the nut 8 and the conical sleeve 6, as shown in Fig.3. The rod turbulizer 5 is rigidly fixed at one end in the nut 8, which is screwed into the housing 1 and compresses the ring 9 and the conical sleeve 6.

The flow sounding unit is a cylindrical chamber 10, hydraulically connected with the cavity 3 of the flow swirling unit, open at the outlet, with the free end of the rod turbulizer 5 located along its longitudinal axis, equipped with an additional adjustable turbulizer 11. The chamber 10 has an inwardly expanding internal bore of the housing at the inlet, turning into a cylindrical one.

In a specific example, an additional adjustable turbulizer (disk) 11 is mounted to move and fix along the free end of the rod turbulizer 5 using a threaded connection. The fixation of the adjustable turbulizer 11 can be achieved, for example, by making keyways - internal on the turbulizer 11 and external - on the free threaded end of the core turbulizer 5, into which, when combined, a removable key (not shown) is inserted.

The diameter of the core turbulizer 5 located in the cavity 3 of the flow swirling unit exceeds the diameter of its free end located in the cylindrical chamber 10 of the flow sounding unit. The plot connecting the different diameters of the core turbulator 5 is made conical.

In the portion of the core turbulizer 5, located in the cavity 3 of the flow swirl unit, longitudinal grooves 12 are made (see FIG. 4), and in the conical section connecting the different diameters of the core turbulator 5, longitudinal grooves are also made, which are a continuation of the grooves 12 made on plot rod turbulizer 5, located in the cavity 3 of the node swirling flow.

Radial through longitudinal slots 7 of the conical sleeve are located opposite the longitudinal grooves 12 of the rod turbulator 5. The conical section connecting the different diameters of the rod turbulator 5 can come into contact with the narrowed part of the cavity 3, bounded by the conical surface of the housing 1 at the exit from it at the entrance to the cylindrical chamber 10. In this case, the passage of fluid is guaranteed by the presence of grooves 12.

The downhole device operates as follows. When the fluid flow is supplied to the tangential inlet 4, it swirls in the cavity 3, unstable turbulent flows of the centers of the vortices are formed. Since the cross section of the cavity 3 in the direction of the linear movement of the flow decreases, the maximum linear flow velocity is reached at the final stage before the destruction of the vortices in the flow sounding unit (in chamber 10). The core turbulizer 5 is located in the zone of increased instability of the currents, reinforced by longitudinal grooves 12 and an additional adjustable turbulizer 11. Of the closest studied mathematical models of vortex flows in the proposed device is a model of a hydrocyclone. It is known that a gas column arises in the center of a hydrocyclone due to a discontinuity in the fluid flow due to the large centrifugal force near the axis of the hydrocyclone and gas evolution from the liquid as a result of intense vortex formation. Thus, the core turbulizer 5 receives complex hydromechanical variable impulses from the flow and, together with this, is located in the region of hydroacoustic cavitation. As a result, all elements of the cavitator (including housing 1) and, most of all, the rod turbulizer 5 are in forced oscillations - resonant vibrations of natural frequencies. The generators of the core turbulizer 5, the cavity 3 and the chamber 10 are calculated in the general problem of the hydrodynamics of vortex flows. The resistance of the walls of the cavity 3 is also taken into account when calculating its variable cross section when solving the variational problem of calculating the best geometry of the cavity 3 and chamber 10. As a result of this effect on the flow of oil-containing products produced, it is destroyed both in cavity 3 and in chamber 10. Excitation of cavitation processes due to the structural design of the device.

A method of manufacturing and operating a downhole device is as follows. Details and assembly units of the downhole device are made. Make it assembly. After the assembly of the downhole device, its oscillation generating unit is tuned to the resonant mode of operation. To do this, the device is placed on the stand, sensors are installed, as well as means for displaying the results of measuring vibro-acoustic vibrations, hydraulically connected to the pump and pumping the fluid flow with the removal of the frequency response. If it is not possible to obtain the maximum values of the power of vibro-acoustic vibrations, stop the flow of liquid, disconnect the outlet pipe, change the position of the additional adjustable turbulator 11 along the free end of the core turbulator, fix it again, connect the outlet pipe and resume the flow of fluid. The operations are repeated until it is possible to adjust the oscillation generating unit to the resonant mode of operation of the downhole device. Typically, the resonant mode of operation of the downhole device is achieved mainly in the frequency response region of 20,000-25,000 Hz (see figure 5). In the tuning operation of the oscillation generating unit, the possibility of some change in the position of the rod turbulizer 5 relative to the point of its fastening along the longitudinal axis can also be used.

During operation of the downhole device, for example, due to erosion wear, the initial geometry of the device elements (rod turbulizer 5, cavity 3, chamber 10, and other parts) is violated, the resistance of the walls of the cavity 3 changes, the hydrodynamics of the vortex flows are violated to one degree or another, and the frequency response of the device may go beyond the resonant mode of operation. Therefore, periodically after lifting the device to the surface, for example, during a major overhaul of a well, its vibration generating unit is tuned to the resonant mode of operation in a similar way. If necessary, revise and replace its parts and assembly units. It is advisable to place the downhole device 13 (see FIG. 5) below the whipping valve (not shown) above the submersible pump 14.

Using the proposal allows for a temporary or irreversible change in the molecular composition of hydrocarbons to lighter molecules by creating a vortex flow with high kinetic energy and resonant excitation, thereby ensuring:

- sufficient for the destruction of the duration and power of the resonant excitation of the extracted oil-containing products by creating a vortex flow with maximum tangential and angular velocities;

- turbulent vortices and cavitation process in a vortex flow, leading to acoustic destruction of the dispersed-aggregate state of oil-containing products and the transformation of chemical bonds;

- the possibility of using the heat and mass-energy exchange process of the vortex flow for the conversion of oil-containing products.

Claims (14)

1. A downhole device for preventing deposits from falling from a stream of extracted oil-containing products, comprising a housing configured to be embedded in a tubing string, an oscillation unit installed in the housing, configured to impact the flow of extracted oil-containing products under the influence of energy said stream, characterized in that the oscillation generating unit is made in the form of swirling and sounding nodes of the flow, wherein the flow swirling unit represents it is a cavity bounded by the conical surface of the body with a tangential inlet and with a rod turbulator located along its longitudinal axis, rigidly fixed at one end, and the flow sounding unit is a cylindrical chamber hydraulically communicated with the cavity of the flow swirling unit, which is open at the outlet and is located along its longitudinal axis free end of the rod turbulator, equipped with an additional adjustable turbulator. 2. The downhole device according to claim 1, characterized in that the additional adjustable turbulator is installed with the possibility of movement and fixation along the free end of the core turbulator. 3. The downhole device according to claim 2, characterized in that the additional adjustable turbulator is installed with the possibility of movement along the free end of the rod turbulator using a threaded connection. 4. The downhole device according to claim 3, characterized in that the additional adjustable turbulizer has an internal, and the free threaded end of the core turbulizer has an external keyway in which the key is located. 5. The downhole device according to claim 1, characterized in that the diameter of the core turbulizer located in the cavity of the flow swirling unit exceeds the diameter of its free end located in the cylindrical chamber of the flow sounding unit, and the section connecting the different diameters of the core turbulizer is conical. 6. The downhole device according to claim 5, characterized in that longitudinal grooves are made in the region of the core turbulizer located in the cavity of the flow swirl assembly. 7. The downhole device according to claim 6, characterized in that in the conical section connecting the different diameters of the core turbulizer, longitudinal grooves are also made, which are a continuation of the grooves made in the section of the core turbulizer located in the cavity of the flow swirl unit. 8. The downhole device according to claim 1, characterized in that it is equipped with a conical sleeve mounted on the conical surface of the body of the flow swirl assembly with radial through longitudinal slots hydraulically connected with the tangential inlet and with the cavity of the flow swirl assembly. 9. The downhole device according to claim 8, characterized in that the conical surface of the body of the flow swirl assembly is two-stage, the first step having the shape of a truncated cone and a conical sleeve with radial through longitudinal slots communicating hydraulically with the tangential inlet and with the cavity knot twisting flow. 10. The downhole tool of claim 8 or 9, characterized in that the radial through longitudinal slots of the conical sleeve are located opposite the longitudinal grooves of the core turbulator. 11. The method of manufacturing and operating the downhole device according to one of claims 1 to 10, characterized in that the parts and assembly units of the downhole device are manufactured, assembled and put into operation, and after assembly of the downhole device, its oscillation generating unit is set up to resonant mode of operation by changing the position of an additional adjustable turbulizer along the free end of the rod tourisulator and pumping the fluid flow on the stand with the removal of the frequency response. 12. The method according to claim 11, characterized in that the adjustment of the oscillation generating unit to the resonant mode of operation of the downhole device is carried out mainly in the frequency response region of 20,000-25,000 Hz. 13. The method according to claim 11, characterized in that the commissioning of the downhole device is carried out by embedding it in the tubing string of the well in the area before the start of the zone of deposition of sediments from the stream of extracted oil-containing products. 14. The method according to claim 11, characterized in that during operation of the downhole device periodically after raising it to the surface, its oscillation unit is tuned to the resonant mode of operation by changing the position of the additional adjustable turbulator along the free end of the core turbulator and pumping the fluid flow on the stand with removal of the frequency response.

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