RU2196217C2 - Downhole acoustic radiator - Google Patents

Abstract

FIELD: oil-gad producing industry designed, particularly, for treatment of bottom-hole formation zone of oil and gas wells. SUBSTANCE: downhole acoustic radiator has body which consists of opened part coming in contact with well fluid by means of windows made in body opened part, and sealed part filled with electric insulating fluid and having air cavity at atmospheric pressure. Body accommodates rod-type magnetostriction transducer whose upper radiating surface is engageable with air cavity. Additionally installed in body is acoustic waveguide made in the form of metal cylinder whose upper end surface is rigidly and coaxially connected with lower radiating surface of transducer. Acoustic waveguide middle part coinciding with its vibration zero point is connected over perimeter rigidly and airtightly with radiator body to separate it into opened and sealed parts. Waveguide lower end part is located in body opened part. Waveguide end surface is soldered with lower radiating surface of transducer. Waveguide middle part coinciding with zero point of its vibration is connected rigidly and airtightly with device body by means of annular weld seam. EFFECT: higher operating reliability and radiation efficiency due to excluded mechanical stresses in radiator design, prevention of radiator corrosion and its higher efficiency in use. 3 cl, 1 dwg

Description

 The invention relates to the oil and gas industry and is intended, in particular, to impact on the bottom-hole zone of oil and gas wells.

A device is known for acoustic impact on the bottom-hole zone of productive formations, comprising a ground-based indicator unit and a power unit connected via a cable to a downhole tool, including a generator, an acoustic emitter made in the form of several rod magnetostrictive vibrators, and a sensor, while the downhole tool is made of three sections and an additional locator of couplings and a converter are introduced into it, and in the lower section, filled with transformer oil and evacuated, ak A generator and pressure compensator, made, for example, in the form of a bellows, in the middle section filled with transformer oil for no more than 3/4 of the volume under atmospheric pressure, a generator is installed, and in the upper section there is a coupling locator, a transducer and a sensor of the measuring system ( see RF patent 2026970, IPC ⁶ E 21 B 43/25 dated 05.06.90, publ. 01.20.95, bull. 2).

 A disadvantage of the known device is that the radiation from the end surfaces of the acoustic emitter occurs in both directions, as a result, the radiation power and, consequently, the effectiveness of the impact on the bottom-hole zone are sharply reduced.

 In addition, the presence in the design of the device of the pressure compensator, made in the form of a bellows, reduces the reliability of the device due to the strong impact on the bellows of the acoustic field, which can damage the mounting of the bellows and disable it.

A device is also known for acoustic impact on an oil and gas bearing formation, comprising a ground control unit connected via a cable to a downhole tool consisting of a generator, an acoustic emitter and a sensor, the downhole tool being made in the form of two parts connected by a cable, with a generator located in the upper part the operating frequency of which is 20-30 kHz, and in the lower one, which communicates with the environment, is an acoustic vibration sensor and acoustic emitters made in the form of piezoceramic x emitters, in addition, at least one acoustic emitter is equipped with at least one acoustic wave reflector installed coaxially with it, having a conical surface with an angle of 90 degrees at the apex facing the emitter, and the distance from the end of the emitter to the reflector surface is selected from the condition of the formation of a standing wave in the downhole pipe (see RF patent 2140519, IPC ⁶ E 21 B 28/00, E 21 B 43/25 of 03/11/98, publ. 10/27/99).

 A disadvantage of the known device is that the reflectors of acoustic waves at an oscillation frequency of less than 40 kHz do not provide their effective perception and reflection, which reduces the effectiveness of the device on the bottom-hole zone.

 In addition, the downhole environment is in contact with the sensor, acoustic emitters and reflectors of acoustic waves located in the lower part of the downhole tool and is a kind of working element of the device used as a heat transfer medium, which, with the instability of the composition and operating parameters of the downhole fluid (fluid) also leads unreliable operation of the device.

The closest technical solution is a borehole thermoacoustic device (borehole acoustic emitter), comprising a support body consisting of an open part in contact with the wellbore fluid through windows made in the open part of the support body and a sealed part filled with an electrical insulating fluid and having an air cavity under atmospheric pressure, while an acoustic reflector and a rod magnetostrictive vibrator are located in the support case (convert spruce), which is rigidly fixed in the support housing above the acoustic reflector, the upper radiating surface of the magnetostrictive vibrator (transducer) interacting with the air cavity, and the distance between the reflecting surface of the acoustic reflector and the radiating end of the magnetostrictive vibrator (transducer) is equal to the odd number of half waves installed in the borehole liquid at the resonant frequency of the magnetostrictive vibrator (transducer), and windows made in the open part of the reference housing located between the radiating end of the magnetostrictive vibrator (transducer) and the reflective surface of the acoustic reflector. In addition, an additional body for heat transfer is pressed onto the rods of the magnetostrictive vibrator (transducer), and the sealed part of the support body is formed by filling the internal cavity of the magnetostrictive vibrator with a heat-resistant epoxy compound, which, after hardening, turns into a monolith with the entire system (see RF patent 2161244, IPC ⁶ Е 21 В 43/00, Е 21 В 43/25 dated 02/09/2000, publ. 12/27/2000).

 A disadvantage of the closest analogue is that the presence of an additional body pressed onto the rods of the magnetostrictive vibrator, as well as the filling of the internal cavity of the magnetostrictive vibrator with a heat-resistant epoxy compound, leads to mechanical stresses of the device elements and a decrease in heat transfer from their surface, which reduces the efficiency of the magnetostrictive vibrator and the effectiveness of the impact bottomhole devices.

 In addition, due to the difference in the coefficients of thermal expansion of the material from which the rods of the magnetostrictive vibrator are made, and the heat-resistant epoxy compound, the tightness of the corresponding part of the support housing at high temperature and pressure drops in the wells can be compromised, which leads to corrosion damage to the emitter, makes the known device unreliable in operation.

 The technical result of the claimed invention is to increase the reliability and efficiency of radiation by eliminating mechanical stresses in the design of the emitter, prevent corrosion damage to the emitter and increase its efficiency.

 The technical result is achieved in that in a borehole acoustic emitter comprising a support body, consisting of an open part in contact with the borehole fluid through windows made in the open part of the support body, and a sealed part filled with an insulating liquid and having an air cavity under atmospheric pressure, in this case, a rod magnetostrictive transducer is located in the support case, the upper radiating surface of the magnetostrictive transducer in interacts with the air cavity; according to the invention, an acoustic waveguide is additionally installed in the support housing, made in the form of a metal cylinder rigidly and coaxially connected with its upper end surface to the lower radiating surface of the magnetostrictive transducer, in addition, the acoustic waveguide in its middle part, which coincides with the zero point of its oscillation, around the perimeter rigidly and hermetically connected to the supporting body, dividing it into open and sealed parts, and the lower end surface of the acoustic wave and it is located in the open part of the support case.

 An acoustic waveguide is connected by its end surface to the lower radiating surface of the magnetostrictive transducer by soldering, and in its middle part, which coincides with the zero point of its oscillation, is rigidly and hermetically connected to the supporting body along the perimeter by means of a circular weld.

 Such a connection of the acoustic waveguide with the lower radiating surface of the magnetostrictive transducer provides good acoustic contact and the necessary mechanical strength.

 In addition, the acoustic waveguide, thanks to its direct connection to the magnetostrictive transducer, effectively removes heat from it into the borehole medium through the open part of the support body, thereby performing the function of a radiator.

 Moreover, the presence of an air cavity with which the magnetostrictive transducer interacts provides a complete reflection of vibrations from its upper radiating surface, which, in turn, due to good acoustic contact with the acoustic waveguide, ensures a doubling of the amplitude of the lower radiating surface of the magnetostrictive transducer and, accordingly, doubling of the amplitude of the lower end surface of the acoustic waveguide.

 The rigid and tight connection of the acoustic waveguide in its middle part with the supporting body along its perimeter allows minimizing the mechanical loss of acoustic energy by fixing the acoustic waveguide at the zero point of its oscillation.

 The absence of mechanical stresses in the design of the borehole acoustic emitter, the minimization of mechanical losses of acoustic energy, the doubling of the amplitude of oscillations of the lower end surface of the acoustic waveguide, the unhindered heat removal from the magnetostrictive transducer to the walls of the emitter’s supporting body and to the acoustic waveguide, and through them to the borehole medium, ensuring stable thermal conditions, can improve the reliability of its work and efficiency, and therefore, the effect of radiation activity.

 The drawing shows the inventive borehole acoustic emitter, a longitudinal section.

 The downhole acoustic emitter comprises a support body 1, consisting of an open part 2 with windows 3 for contacting the well fluid and a sealed part 4 filled with electrical insulating fluid 5 and having an air cavity 6 under atmospheric pressure.

 An acoustic waveguide 7 and a rod magnetostrictive transducer 8 are located in the supporting housing 1, the excitation windings 9 are superimposed on its rods.

 The upper radiating surface 10 of the magnetostrictive transducer 8 interacts with the air cavity 6.

 The acoustic waveguide 7 is made in the form of a metal cylinder rigidly and coaxially connected by its upper end surface to the lower radiating surface of the magnetostrictive transducer 8 by soldering 11, for example, silver solder.

 In addition, the acoustic waveguide 7 in its middle part, which coincides with the zero point of its oscillation, is rigidly and hermetically connected to the supporting body 1 along the perimeter, dividing it into open 2 and hermetic parts 4 by means of a circular weld 12.

 The lower end surface 13 of the acoustic waveguide 7 is located in the open part 2 of the support housing 1.

 On the rod part of the magnetostrictive transducer 8 is an electrical winding 14 connected to the output of the borehole or surface alternating voltage generator 15.

 The seal of the support housing 1 on the side of the magnetostrictive transducer 8 is provided by a bridge 16 with sealing rubber rings 17, in which an oil seal 18 with a screw 19 is located for outputting the electrical winding 14.

 From the side of the acoustic waveguide 7, a tip 20 is mounted on the support housing 1.

 The device operates as follows.

 From the borehole or surface generator 15, an alternating voltage of the operating frequency corresponding to the resonant frequency of the magnetostrictive transducer 8, for example, 20 kHz, is supplied to the electric coil 14.

 At the same time, a bias current, for example, 2 A, is supplied to the same electrical winding 14 from the same generator. The rod magnetostrictive transducer 8 transmits vibrations to the acoustic waveguide 7, and the latter, in turn, through the windows 3 to the borehole environment.

 The inventive borehole acoustic emitter allows to increase the efficiency of impact on the bottom-hole zone of oil and gas wells by doubling the amplitude of oscillations of the lower end surface of the acoustic reflector, and also to ensure the reliability of the emitter by eliminating mechanical stresses, preventing corrosion damage, the constancy of the temperature regime of the emitter and simplicity of design.

Claims (3)

 1. A downhole acoustic emitter comprising a support body, consisting of an open part in contact with the wellbore fluid through windows made in the open part of the support body, and a sealed part filled with an insulating liquid and having an air cavity under atmospheric pressure, while in the support body a rod magnetostrictive transducer is located, and the upper radiating surface of the magnetostrictive transducer interacts with the air cavity, distinguishes characterized in that an acoustic waveguide made in the form of a metal cylinder is rigidly and coaxially connected with its upper end surface to the lower radiating surface of the magnetostrictive transducer in addition to the acoustic waveguide in its middle part, which coincides with the zero point of its vibration, around the perimeter it is rigidly and hermetically connected to the supporting body, dividing it into open and sealed parts, the lower end surface of the acoustic waveguide being olozhena in the open part of the supporting body.  2. The downhole acoustic emitter according to claim 1, characterized in that the acoustic waveguide is connected by its end surface to the lower radiating surface of the magnetostrictive transducer by soldering.  3. The downhole acoustic emitter according to claim 1, characterized in that the acoustic waveguide in its middle part, which coincides with the zero point of its oscillation, is rigidly and hermetically connected to the housing along the perimeter by means of a circular weld.