RU2164829C1 - Acoustic irradiator for well - Google Patents

Abstract

FIELD: systems for acoustic irradiation of beds, for example, for intensified production of oil, water and other fluids from wells. SUBSTANCE: acoustic irradiator includes piezotransducers and sleeves arranged between them and secured to central rod, upper and lower heads, elastic casing filled with compensation liquid, fluid-tight electric current lead and contact device for cable tip, both placed in upper head. Irradiator has signal procession circuit having adder and signal converter; said circuit is connected by means of fluid-tight electric current lead, single-core cargo carrying geophysic cable with ground equipment. Piezotransducers are made of longitudinally polarized, electrically connected in parallel piezoceramic washers. At least two piezoceramic washers may operate as pressure pickup electrically connected with circuit for signal procession. EFFECT: possibility for accurate continuous tuning of piezoceramic transducers to maximum admissible acoustic pressure at working process, enhanced comfort of maintenance of irradiator. 5 cl, 5 dwg

Description

 The invention relates to devices for acoustic impact on reservoirs, including for the intensification of oil, water and other fluids from wells.

 Known acoustic emitters [1,2] consisting of vibrators, a shaft, a housing and a current-carrying device. The disadvantage of these emitters is the lack of operational adjustment of parameters during operation.

 Known acoustic emitter [3], consisting of vibrators spaced by intermediate sleeves located on the shaft, a housing filled with contact fluid, a sealed current lead and contact device installed in the upper head. The disadvantage of this device is the lack of operational adjustment of the modes of acoustic impact on the reservoir.

 Also known is the acoustic emitter [4], adopted for the prototype, containing piezoelectric transducers and bushings between them, mounted on the central rod, upper and lower heads, an elastic casing filled with compensation fluid, a sealed current lead, and a contact device for a cable lug installed in the upper head.

 The disadvantages of this emitter are: the lack of operational adjustment of the acoustic impact on the formation during the operation of the emitter, the complexity of maintenance, the possible pickup of the emitter in the well due to the bloating of the elastic body when rising from the well with a high gas factor.

 Task.

 An object of the invention is the implementation of accurate continuous tuning of piezoceramic transducers during operation, used as vibrators, to the maximum developed acoustic pressure, as well as improving the ease of maintenance of the emitter during its operation.

 Features.

 To solve the technical problem, in contrast to the known acoustic emitter, the emitter is equipped with a signal processing unit, the unit consists of an adder and a signal converter, and is connected through a sealed current lead, a contact device and a single-core load-bearing geophysical cable with ground equipment, piezoelectric transducers are made of longitudinally polarized electrically connected in parallel to the piezoceramic washers, while at least two piezoceramic washers are made with the possibility of I function of the pressure sensor, connected electrically to the signal processing unit, and formed with segments, electrically insulated from the rest of the surface of the washer, area segments is 5-25% of the total surface area of the washer. Each piezoelectric transducer is equipped with an individual reinforcing device, which makes it possible to produce piezoelectric transducers with almost the same resonant frequency and high quality factor, which leads to an increase in the efficiency of the emitter as a whole due to the balanced parameters of the piezoelectric transducers installed in it. A safety valve is installed in the upper part of the emitter, tuned to a predetermined pressure drop value inside and outside the emitter. When the emitter is removed from the well, excess pressure is generated that forms in the inner cavity of the emitter when it is raised due to the release of well gas that has penetrated through the elastic casing and dissolved in it from the compensation fluid, which prevents the inflation of the elastic casing and, therefore, the emitter is stuck in the wellbore. The introduction of quick-disconnect assemblies for sealing the elastic casing and locking threaded joints allows to simplify the assembly-disassembly of the emitter and reduce the time for its maintenance. The implementation of the valve for pumping and refueling the compensating fluid into the emitter self-locking, in addition to the ease of maintenance of the emitter, prevents the expansion fluid from flowing into the environment when the emitter is undocked from the filling device.

List of drawings
In FIG. 1 shows the design of the emitter (section) - the upper and middle parts of the emitter,
in FIG. 2 - the design of the emitter (section) - the middle and lower parts of the emitter,
in FIG. 3 - design of a piezoelectric transducer,
in FIG. 4 - connection diagram of piezoceramic washers in a piezoelectric transducer,
in FIG. 5 - block diagram of the connection of the emitter to ground equipment
where 1 is a piezoelectric transducer, 2 is a rod, 3 is a spacer sleeve, 4 is an upper head, 5 is a lower head, 6 is a rod locking device, 7 is a translucent elastic casing, 8 is a rubber o-ring, 9 is a glass with an inner cone, 10 - nut with collet clamp, 11 - sealed current lead, 12 - contact device, 13 - safety valve, 14 - self-locking valve, 15 - signal processing unit, 16 - compensation fluid, 17 - protective cap, 18 - piezoceramic washers, 19 - piezoceramic electrically isolated washers segments, 20 - electrically insulated segments of washers, 21 - single-core load-bearing geophysical cable, 22 - feedback block of ground equipment, 23 - master oscillator, 24 - indication unit, 25 - tube, 26 - nut, 27 - overlay.

 Description of the invention.

 The emitter (Fig. 1 and 2) consists of several piezoelectric transducers 1, mounted on the Central rod 2 using spacer sleeves 3 at a distance from each other, equal, for example, λ / 2, where λ is the wavelength in the compensation fluid under conditions of borehole pressure and temperature upper 4 and lower 5 heads with a device for locking 6 rod; a translucent elastic casing 7, mounted on the heads using a quick-detachable sealing unit, which includes, for example, rubber o-rings 8, a glass 9 with an inner cone, interacting through a casing with a cone on the upper (lower) head and covering the casing in the area of installation of rubber rings, and nut with collet for locking; sealed current lead 11 and contact device 12 for a geophysical cable lug mounted in the upper head; a safety valve 13 installed in the upper head, which ensures the degassing of the internal cavity of the emitter when it is raised from the well, especially with an increased gas factor; a self-locking valve 14 for filling the inner cavity of the emitter with compensation fluid 16 installed in the lower head; a signal processing unit 15 connected electrically to piezoelectric transducers; compensation dielectric fluid 16, injected into the internal cavity of the emitter, for example, transformer oil ATM-65 or other similar fluid with high electrical insulation properties; a cap 17 covering the lower part of the emitter and protecting it during descent into the well.

 Piezoelectric transducers (Fig. 3) consist of longitudinally polarized, electrically connected in parallel piezoelectric washers 18 and include at least two piezoceramic washers 19, configured to perform the function of a pressure sensor, and made with segments 20 electrically isolated from the rest of the surface of the washer (fig. . 4). The area of the segments is 5-25% of the total surface area of the piezo washer, which ensures the stable isolation of the information signal with a minimum of decrease in the acoustic power of the washer in the operating mode. The segments are electrically connected to the signal processing unit 15, which is connected through the sealed current lead 11, the contact device 12 and the load-carrying geophysical cable 21 (Fig. 5) to the feedback block 22, which is part of the ground equipment and generates a control signal to the master oscillator 23. This allows you to quickly adjust the parameters of the electric signal to the piezoelectric transducers and thereby maximize the developed acoustic pressure of the emitter. The design of the piezoelectric transducer provides for the selective selection of piezoceramic washers according to the resonance frequency and impedance value, which allows to obtain a given impedance of the entire assembly, which increases the efficiency of the piezoelectric transducer. In addition, the piezoelectric transducers have a reinforcing device consisting of a tube 25 with threads at the ends and nuts 26, in order to ensure self-alignment with a spherical surface that interacts with the conical surface of the plates 27, which ensures longitudinal compression of the piezoceramic washers during assembly to tune to a given resonant frequency and improving the quality factor of piezoceramics. The introduction into the composition of the piezoelectric transducer of piezoceramic washers, which perform the function of pressure sensors, and an individual reinforcing device provide the ability to manufacture piezoelectric transducers with the same resonant frequency, simplicity and ease of assembly, virtually eliminates errors during electrical installation of the emitter.

 The signal processing unit 15 is a radio electronic circuit from an adder and a signal converter mounted on an insulating chassis around the rod and designed to convert signals from segments of piezoceramic washers, as well as for electrical isolation of the signal from the sensors and the supply voltage to the piezoelectric transducers. The signal processing unit allows you to continuously transmit a DC information signal from the emitter to the ground equipment through the supply conductor of the load-bearing geophysical cable, thereby using a single-core geophysical cable widely used in fields to connect the emitter to the ground equipment, which further increases the usability of the emitter.

 The device for locking threaded connections is made, for example, in the form of a collet clamp, which provides reliable locking of the threaded connection of the rod with the heads under the influence of prolonged all-frequency vibrations and the possibility of multiple assembly-disassembly of the emitter.

The emitter (Fig. 1 and 2) works as follows. An alternating voltage of a sinusoidal form with a resonant frequency of the piezoelectric transducers of the emitter U _G (Fig. 5) is supplied to the emitter, lowered into the well, through a single-core load-bearing geophysical cable 21 with a tip from ground equipment. Thanks to the piezoelectric effect, electrical energy is converted in piezoelectric transducers 1 into mechanical energy with the appearance of a longitudinal acoustic wave. Due to the installation of piezoelectric transducers at a half-wave distance in the compensation fluid 16 located in the internal cavity of the emitter, between the piezoelectric transducers, and between the heads and piezoelectric transducers, acoustic energy is rotated in the radial direction relative to the axis of the emitter, which makes it possible to realize a disk form of directivity. Under the action of pressure in the segments 20 isolated from the rest of the surface of the piezoceramic washers, an alternating electric signal U _D arises, the value of which characterizes the operation of the piezoelectric transducer (the maximum voltage in resonance). The signals from the segments of the piezoelectric transducers are fed to the adder of the signal processing unit, then to the signal converter of the unit in which the signal is converted to a direct current signal, and the resulting signal U _K passes through a geophysical cable to the feedback unit 22, which is part of the ground equipment, where the formation _In the control signal U for driving generator 23. during operation of the emitter under the influence of various, not always taken into account in advance factors (vibration, ambient pressure, temperature, et al.), it is possible unbalance of piezo resonant frequency, which causes a redistribution of power between the piezoelectric transducers and a general decrease in the sound pressure. At the same time, the values of the signals from the segments also decrease. The control signal generated in the feedback block acts on the master oscillator in the direction of increasing the value of the resulting signal from the sensors. The introduction of pressure sensors directly into the piezoelectric transducers allows you to continuously adjust the parameters (frequency, phase, voltage, etc.) of the electric signal supplied to the piezoelectric transducers in order to obtain the maximum acoustic impact of the emitter on the formation. For visual inspection, the parameters of the electrical signal are fed to the display unit 24.

 In the process of operation of the emitter in the well through a translucent elastic casing 7, made, for example, from the PB-2 polymer composition, penetrates into the compensation fluid 16 and, under the influence of the borehole pressure, the gas in the well dissolves in it, which, when the emitter rises from the well due to the phenomenon decompression can cause the casing to swell, and as a result, the emitter is stuck in the well. The safety valve 13, installed in the upper head of the emitter, and made, for example, in the form of a nipple or spring valve, is activated when the calculated differential pressure is exceeded and discharges part of the gas together with part of the compensation fluid into the well, while the diametrical size of the casing does not exceed the allowable for this well size. To compensate for the lack of compensation fluid in the emitter, a self-locking valve 14 is used, which, in addition to simplifying the process of refueling the emitter, also prevents spontaneous outflow of the compensation fluid into the environment when the emitter is undocked from the filling device.

 Industrial application.

 Downhole acoustic emitter is made on common industrial elements.

 The borehole acoustic emitter passed industrial testing at the Vatiegan field Zap. Siberia in 1999

Sources of information
1. Patent SU N 683810, 09/05/1979, IPC B 06 B 1/06, H 04 R 17/00;
2. Patent SU N 1693576, 11.23.1991, IPC G 01 V 1/40;
3. Patent SU N 1581389, 07/30/90, IPC B 06 B 1/06, 1/08;
4. Patent RU N 2107557, 03/27/1998, IPC B 06 B 1/06, 1/08.

Claims (5)

 1. A downhole acoustic emitter containing piezoelectric transducers and bushings between them, mounted on a central rod, upper and lower heads, an elastic casing filled with compensation fluid, a sealed current lead and a contact device for a cable lug installed in the upper head, characterized in that the emitter is equipped with a signal processing unit, the unit consists of an adder and a signal converter and is connected through a sealed current lead, a contact device and a single-core geophysical load-bearing cable with ground equipment, piezoelectric transducers made of longitudinally polarized, electrically connected in parallel piezoelectric washers, while at least two piezoceramic washers are configured to perform the function of a pressure sensor connected electrically to the signal processing unit.  2. The downhole acoustic emitter according to claim 1, characterized in that the piezoceramic washers that perform the function of a pressure sensor are made with segments electrically isolated from the rest of the surface and constitute 5 to 25% of the surface area of the washer.  3. The downhole acoustic emitter according to claim 1, characterized in that each piezoelectric transducer is equipped with an individual reinforcing device.  4. The downhole acoustic emitter according to claim 1, characterized in that it is equipped with a safety valve installed in the upper head, and in the lower head the emitter is equipped with a self-locking valve.  5. The borehole acoustic emitter according to claim 1, characterized in that it has quick-disconnect assemblies for sealing an elastic soundproof casing, which includes rubber o-rings, a cup with an inner cone, a casing covering the area where the rubber rings are installed, and a nut with a collet clamp for locking threaded connections.

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