RU2353759C1 - Facility for acoustic effect onto walls of well bore - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention refers to operation of well bores, particularly to means of acoustic effect onto walls of well bore and can be implemented, for example, at oil extraction. The facility for acoustic effect onto walls of well bore includes an ultrasonic generator created by several electrically connected between them functional blocks, a downhole apparatus in form of a hollow case and an ultrasonic converter, mainly magnetostrictive. The ultrasonic converter is mechanically connected with the downhole apparatus and also with the ultrasonic generator by means of a field coil. The functional blocks of the ultrasonic generator are successively arranged one after another and installed in the downhole apparatus, the case of which is made sectional. The ultrasonic generator is installed in one of the sections of the downhole apparatus and is additionally equipped with at least one radiating link, which is output from the case of the downhole apparatus.

EFFECT: reduction of power losses.

12 cl, 1 dwg

Description

The invention relates to the field of operation of boreholes, and in particular to means of acoustic impact on the walls of the well, and can be used, for example, in oil production.

A device for acoustic impact on the walls of the well, providing an increase in oil flow, in which the source of acoustic impact, installed in the area of the oil-bearing formation, is a hydraulic vibrator [1].

The disadvantage of this device is that its vibrator operates at a frequency of several hundred hertz, as a result of which the walls of the well are subjected to the destructive effect of low-frequency oscillations.

A device for acoustic impact on the walls of the well is also known, including a magnetostrictive transducer installed in the zone of the oil-bearing formation, an ultrasonic generator located on the surface of the earth, and a power cable that electrically connects the ultrasonic generator and the transducer [2].

The disadvantage of this device, operating in the ultrasonic frequency range more favorable for the walls of the well, is the presence of large energy losses in the supply cable connecting the ground and borehole parts of the device.

In addition, it is known a device for acoustic impact on the walls of the well, containing interconnected via a power cable ultrasonic generator (for example, type UZG-3-4), which due to the large overall dimensions of the body (700 × 1500 × 700 mm) exceeding the diameter of the well , is located on the surface of the earth, and an acoustic emitter, which (installed in the cavity of a borehole projectile having a hollow cylindrical body) is formed by a frequency multiplier, a magnetostrictive transducer (according to the description of It is made without a radiating element) and with an electric heater in the form of a heating element. The large overall dimensions of the ultrasonic generator of this device are largely due to the fact that its functional blocks have a spatial arrangement, since their components, depending only on their own dimensions and weights, are mounted on different chassis mounted both on the base and on the walls of the case [3].

Such a constructive solution, in comparison with the one described above, significantly complicates the device, but allows to reduce energy losses in the power cable. However, it does not completely eliminate these losses, since the power cable connecting the surface and borehole parts of the device, i.e. The ultrasonic generator and transducer still have a considerable length.

This is the main disadvantage of this device, which in its technical essence and the result achieved when using it, is the closest to the proposed and adopted as a prototype.

The second significant disadvantage of this device is that its magnetostrictive transducer (for example, rod type) is made without a radiating link. As a result of this, ultrasonic vibrations propagate along the axis of the well and do not have a direct focus on the walls of the well. As a result of this, the total duration of acoustic impact on the walls of the well increases, and along with it increases the energy consumption.

The technical result, the achievement of which the invention is directed, is to reduce energy losses.

This technical result in a device for acoustic impact on the walls of the well, including an ultrasonic generator formed by several electrically interconnected functional blocks, a downhole projectile in the form of a hollow body and an ultrasonic transducer, mainly magnetostrictive, which is installed in the cavity of the downhole tool body and connected via an excitation winding with an ultrasonic generator is achieved due to the fact that the functional blocks of the ultrasonic generator ora performed sequentially arranged one after another and are mounted in a downhole projectile body is made sectioned, with the ultrasound transducer mounted in one of the sections of the borehole and the projectile is further provided with at least one radiating element, which is derived from a downhole housing shells.

The achievement of the technical result is also facilitated by the fact that:

- the radiating element is made in the form of a transformer of the direction of oscillation;

- the transformer of the direction of oscillation is made predominantly composite, and the dimensions of each component are resonant;

- the oscillation direction transformer is made mainly in the form of a hollow cylinder, one end of which is rounded, and the other is equipped with a plug and connected to the working surface of the ultrasonic transducer;

- the oscillation direction transformer is made primarily of a titanium alloy;

- sections of the body of the downhole tool are sealed and isolated from one another;

- sections of the body of the downhole tool are made mainly with different overall dimensions;

- sections of the body of the downhole tool are located mainly sequentially one after another;

- sections of the body of the downhole tool are interconnected mainly with the possibility of their relative movement, at least in one plane;

- in one section of the body of the downhole tool are fully or partially constituent elements of at least one functional block of an ultrasonic generator;

- the ultrasonic transducer is installed mainly in the extreme section of the downhole projectile;

- an ultrasonic transducer is installed in the lower section of the downhole tool.

The invention is illustrated in the drawing, which schematically shows the proposed device.

The following is an example of a specific implementation of the proposed device, not excluding other options for its implementation in the scope of the claims.

The ground part of the device is a well cover 1, through which, using rollers 2 and 3 mounted on special supports (not shown), an electric cable 4 connected to an industrial electrical network (380 V, 50 Hz) and a metal cable 5 that holds downhole projectile at a given depth. The power cable interconnected with the control panel 6 (“ON” and “OFF” buttons, power adjustment knob), and cable 5 have the required length and are wound on rotating drums 7 and 8, which are installed on special racks (not marked).

The borehole part of the device, providing an acoustic effect on the walls 9 of the well, consists of a borehole projectile 10, an ultrasonic generator 11, an ultrasonic transducer 12 and a radiating element 13.

The downhole tool 10 is made in the form of a hollow cylindrical body, which, by its height, is divided by five special partitions (not indicated) into five airtight and isolated sections 14. The body of the downhole tool is equipped with covers (not marked), the upper of which has an opening for the passage of the electric cable 4 and interconnected with the cable 5. Sections 14 of the downhole tool 10 are made with the same overall dimensions (outer diameter, height, wall thickness), arranged sequentially one after the other (along one axis common to them ) and are tightly interconnected, i.e. without the possibility of their relative movement in horizontal and vertical planes.

The ultrasonic generator 11 is formed by an electrically interconnected control panel 6 and several functional units 15 (for example, a power supply unit, a power unit, a magnetization unit, a control unit), which are arranged sequentially one after the other in the borehole casing, located in its separate sections 14 and are electrically interconnected through partition walls.

An ultrasonic double-rod magnetostrictive transducer 12, for example, of a half-wavelength, is installed in the lower (extreme) section of the downhole tool 10. It has one working surface (rubber is glued to its second radiating surface, not shown) and is equipped with an excitation winding 16, which is laid on its rods and connected to the output unit of the ultrasonic generator 11.

The radiating link 13 of the ultrasonic transducer 12 is made in the form of a transformer of the direction of oscillation, which is made of a titanium alloy (VT-3) and removed from the body of the downhole projectile through its bottom cover. It is a hollow cylinder, one of the ends of which is rounded, and the second is plugged with a plug and rigidly connected to the working surface of the ultrasonic transducer 12. Moreover, the hollow cylinder is made integral (in the form of separate waveguides 17 having resonant dimensions) and can have a total length of more than one meters, while the length of the ultrasonic generator 11 (high enough power) does not exceed 55-60 centimeters.

The proposed device, when creating the ultrasonic part of which you can use publicly available information (for example, a book by V.O. Abramov, O.V. Abramov, etc. Powerful ultrasound in metallurgy and mechanical engineering, M., Janus-K, 2006, p. 17- 66), is operated as follows.

Previously, the borehole projectile 10 is lowered by means of a cable 5 into the borehole 9 and placed in the desired zone, for example, in one of the sections of the oil-bearing formation. Then, including the corresponding button on the control panel 6, electric energy is supplied to the ultrasonic generator 11 via an electric cable 4 from an industrial frequency network, which it converts into an ultrasonic frequency current supplied to the excitation winding 16 of the ultrasonic transducer 12. Under the action of the magnetic field generated by the excitation winding 16, the transducer 12 begins to perform longitudinal vibrations with an ultrasonic frequency, which are transmitted to the radiating link 13. The longitudinal vibrations of the transducer 12, arriving into radiating link 13, i.e. in the transformer, the directions of oscillations are converted by him into radial vibrations of its side surface (shown in the drawing by horizontal arrows). These vibrations propagate through the fluid filling the well, and act on the oil-bearing formation, providing, ultimately, an increase in oil flow. After the appropriate time of acoustic impact on the walls of the well, all the equipment is disconnected from the electrical circuit and bring it to its original position.

Other examples of the specific implementation of the proposed device, first of all, include various variations with the implementation of sections of the downhole projectile and the placement of the functional blocks of the ultrasonic generator and their constituent elements. This is very relevant at the stage of development and creation of the device and does not affect the efficiency of its operation during operation.

Sections of the downhole projectile (all or part of them) can be made with different overall dimensions from the same or from different materials. They can be located next to one another and interconnected to ensure the possibility of their relative movement in at least one plane. At the same time, in each of them, it is possible to position fully or partially the constituent elements of two or three functional blocks of the ultrasonic generator.

The effectiveness of the proposed device is determined mainly by the design of the ultrasonic transducer and emitting link and their number. In this part, it should be noted that the transducer can be made magnetostrictive annular or piezoceramic and it can be located in the center of the downhole tool or in its upper part. The best option is when a rod magnetostrictive transducer is used and each of its radiating (working) surfaces is equipped with an appropriate radiating link.

As shown by experimental studies, in comparison with the known device, the use of modern components, the sequential arrangement of the functional blocks of the ultrasonic generator and their placement in the downhole tool allow to obtain an almost complete reduction in energy losses, because there is no power cable between the generator and the transducer, and equipping the ultrasonic transducer with a radiating link transforming the direction of oscillation propagation reduces the total duration of the acoustic impact on the borehole walls and thereby significantly reduces the total energy loss.

Thus, the proposed device allows for a simple and fairly reliable achievement of the above technical result.

Information sources

1. Gadiev S.M. Use of vibrations in oil production. M., "Nedra", 1977.

2. Makarov V.N. et al. The first results of the use of ultrasound in the fight against salt deposition in oilfield equipment at the Shaim field. - "Oilfield business", M., VNIIOENT, 1978, No. 6, p.23.

3. Copyright certificate of the USSR, No. 989048, MKI E21B 43/00, 1981

Claims (12)

1. Device for acoustic impact on the walls of the well, including an ultrasound generator formed by several electrically interconnected functional blocks, a borehole shell in the form of a hollow body and an ultrasonic transducer, mainly magnetostrictive, which is mechanically interconnected with the borehole shell and connected to the ultrasonic generator by means of an excitation coil characterized in that the functional blocks of the ultrasonic generator are sequentially split married one by one and installed in the downhole tool, the casing of which is made sectional, while the ultrasonic transducer is installed in one of the sections of the downhole tool and is additionally equipped with at least one radiating link, which is removed from the body of the downhole tool. 2. The device according to claim 1, characterized in that the radiating element is made in the form of a transformer of the direction of oscillation. 3. The device according to claim 2, characterized in that the oscillation direction transformer is made predominantly composite, and the dimensions of each component are resonant. 4. The device according to claim 2, characterized in that the oscillation direction transformer is made predominantly in the form of a hollow cylinder, one end of which is rounded and the other is equipped with a plug and connected to the working surface of the ultrasonic transducer. 5. The device according to claim 2, characterized in that the oscillation direction transformer is made primarily of titanium alloy. 6. The device according to claim 1, characterized in that the sections of the body of the downhole tool are sealed and isolated from one another. 7. The device according to claim 1, characterized in that the sections of the body of the downhole tool are made mainly with different overall dimensions. 8. The device according to claim 1, characterized in that the sections of the body of the downhole tool are located mainly sequentially one after another. 9. The device according to claim 1, characterized in that the sections of the body of the downhole tool are interconnected mainly with the possibility of their relative movement in at least one plane. 10. The device according to claim 1, characterized in that in one section of the body of the downhole tool are fully or partially constituent elements of at least one functional block of an ultrasonic generator. 11. The device according to claim 1, characterized in that the ultrasonic transducer is installed mainly in the extreme section of the downhole tool. 12. The device according to claim 1, characterized in that the ultrasonic transducer is installed in the lower section of the downhole tool.