RU2162519C2 - Method of acoustic treatment of well producing zone and device for method embodiment - Google Patents

Abstract

FIELD: methods and devices for treatment of well producing zone. SUBSTANCE: method is based on excitation of downhole acoustic radiator by electric signal of frequency process band, conversion of electric signal into energy of acoustic vibrations. Short-range well producing zone is exposed to acoustic vibrations by the sum of electric signals of a series of process frequency band. Long-range well producing zone is exposed to low-frequency acoustic vibrations of combination different frequencies of process band. Device for embodiment of the method has a series-connected control unit based on multichannel master oscillator and phase-pulse modulator, generating device having a series of gated power amplifiers, matching device, cable, downhole acoustic radiator and power rectifier. Rectifier input is connected with terminals of primary power supply mains. Control voltage busbar in the device is connected to control input of multichannel phase-pulse modulator. EFFECT: higher well flow rate, particularly, low-productive wells; reduced fond of wells out of operation. 5 cl, 2 dwg

Description

 The invention relates to the oil and gas industry, can be used to increase the flow rate of unproductive wells and for the rehabilitation of wells that are considered unpromising.

 Among the methods of influencing the bottom-hole zone of oil and gas wells in order to increase their productivity, a large place has recently been given to the method of acoustic exposure, which ensures the restoration and improvement of the influx of oil and gas from the reservoir into the production zone [1, 2].

 Known methods of acoustic processing based on the excitation of acoustic vibrations in the productive zone of the formation by downhole emitters, the effectiveness of which is achieved by placing the emitter near the processing zone [1, 3, 4].

 Known methods are divided by the frequency range of the acoustic impact. Methods of electro-hydraulic, shock, explosive and hydrodynamic effects initiate mainly low-frequency acoustic vibrations [5], which can affect the reservoir, providing increased reservoir pressure and involvement of stagnant zones of the reservoir. The greatest effectiveness of acoustic exposure is achieved if the frequency of exposure is close to the dominant frequencies determined by the geophysical characteristics of the formation and lying in the low-frequency region [6].

 The above methods of acoustic exposure using explosive, hydrodynamic, and other pulsed-type emitters do not make it possible to realize a low-frequency acoustic effect that adapts to geophysical characteristics, since the spectrum of their radiation is unregulated.

 Known methods of high-frequency acoustic impact on the production zone of the well in the technological frequency range of 10 - 25 kHz, implemented using piezoelectric or magnetostrictive emitters [3, 7, 8]. Under the influence of high-frequency acoustic vibrations, the physicochemical characteristics of the reservoir change [3, 4], which leads to the cleaning of the collector from contamination. However, their area of influence is limited to the near zone of the well due to the rapid attenuation of high-frequency oscillations.

 Each of these methods, low-frequency or high-frequency, implemented separately, does not provide a wave effect on a significant area of the reservoir and, therefore, cannot provide a significant increase in oil recovery.

 The technical solution closest to the one proposed in terms of technical essence and the totality of essential features is the method described in the book [3]. The known method is based on the excitation of a borehole acoustic emitter with an electric signal of the technological frequency range, the conversion of the energy of the electric signal into the energy of acoustic vibrations acting on the treated zone of the well at intervals of perforation.

 Implementation of the prototype method is carried out using the prototype device described in [10] and containing a serially connected control device made on a master oscillator and a phase-pulse modulator, a generator device, a matching device, a cable, a borehole acoustic emitter, and also a power rectifier, the input of which connected to the terminals of the primary power supply network, and the output to the power bus of the generating device.

 In accordance with the known method and device for its implementation, the treatment of the productive zone of the well is carried out by tonal acoustic vibrations, the frequency range of which lies in the technological range of 15 - 25 kHz. The selected frequency range corresponds to the technical capabilities of the effective operation of acoustic emitters, implemented in the dimensions of downhole shells with a diameter of not more than 110 mm, which is determined by the diameter of the well casing.

 The acoustic power of known downhole emitters made of magnetostrictive or piezoelectric transducers does not exceed 0.5 - 5 kW at conversion frequencies of at least 10 kHz. Acoustic fluctuations in the technological frequency range decay rapidly when the collector propagates in the rocks, and the effective processing area does not exceed 0.5–1 m of the near-well zone [4]. You can increase the impact zone by lowering the frequency of acoustic vibrations, which contradicts the technical capabilities of the efficient operation of downhole emitters. Thus, a disadvantage of the known method and device is the low efficiency of the treatment of productive formations associated with the well production zone.

 The objective of the present invention is to increase the production rate of the well by implementing powerful acoustic radiation in the extended technological high-frequency range of the technological range and in the low-frequency range, which ensures the excitation of both near and far from the well productive layers.

To solve the problem in a known method of processing a productive zone of a well, based on the excitation of a borehole acoustic emitter by an electric signal of a technological frequency range, converting the energy of an electric signal into the energy of acoustic vibrations acting on a treated zone of a well in perforation intervals, the following operations are additionally performed:
- a downhole acoustic emitter is excited by an electric signal, the spectrum of which is formed as the sum of the electrical signals of a number of frequencies in the technological range; acoustic vibrations of a number of frequencies of the technological range affect the near productive zone of the well;
- the far productive zone of the well is affected by low-frequency acoustic oscillations of the Raman differential frequencies of nonlinear interaction of signals of a number of frequencies in the technological range.

 The greatest effect of using the proposed method is achieved when the initial frequencies of the technological range are set in the range of 10 - 60 kHz, taking into account the geophysical characteristics of the near productive zone of the well so that the Raman difference frequencies are in the range of 20 - 4000 Hz, taking into account the geophysical properties of the far productive zone of the well.

 The technical and technological indicators of the proposed method are most effective if the treatment of the productive zone of the well in the perforation interval is carried out in increments of 1 - 2 m with a borehole acoustic emitter with an active base length of 0.5 - 1.5 m, acoustic power of 0.5 - 5 kW moreover, at each step, the downhole acoustic emitter is excited first by a tonal frequency-modulated electrical signal for 0.1 to 1 hour, and then by an electrical signal in the form of the sum of the electrical signals of a number of technological frequencies about the range, including frequency-modulated, for 1 to 4 hours.

 The implementation of the proposed method is possible when the sum (beat) of two high-frequency components is selected as the sum of the electrical signals of a number of frequencies in the technological range, and one of these components is modulated in frequency in the low-difference-frequency range.

The technical effect of using the invention is as follows:
- since the geophysical parameters of the reservoir and the near-wellbore zone (viscosity, porosity, scale of stratification, etc.) have a significant range of changes, and the physicochemical mechanisms that determine the mode of acoustic exposure (viscosity change, heat generation, microflows, cavitation effects, local resonances, etc. . [3, 4], frequency-dependent, the impact of the spectrum of high-frequency components, the range of which is expanded to 10 - 60 kHz, allows you to excite various processes for improving the collector near the zone of development with their own frequency characteristics;
- with the simultaneous emission of high-frequency signals of two or more frequencies, their interaction due to the nonlinearity of the medium causes the appearance of difference (low-frequency) oscillations; signals of these frequencies, attenuating much longer than the primary high-frequency signals, penetrate into the far productive zone; at the same time, resonant mechanisms of those spatial scales are also included, including in the near zone, which can be activated at lower frequencies lying in the range of 20 - 4000 Hz, which coincides with the range of dominant frequencies of the layers [6];
- control of components in the high-frequency and low-frequency regions of the emitted signal when choosing the frequencies of the technological range and Raman differential frequencies, taking into account the geophysical characteristics, allows the most effective activation of the physicochemical mechanisms of various spatial scales;
- changing the frequencies of the technological range and Raman difference frequencies during the exposure process, as well as the emission of frequency-modulated signals gives additional opportunities to expand the spectrum of acoustic vibrations and provides adaptation of the acoustic parameters to changing conditions during processing;
- treatment of the productive zone of the well with complex acoustic vibrations with a power of 0.5 - 5 kW, generated by a borehole emitter with an active base of 0.5 - 1.5 m in steps of 1 - 2 m sequentially at each step with a high-frequency signal to “swing” the near zone for 0.1 - 1 hour and a signal of Raman difference frequencies for exposure to low-frequency oscillations in the far zone, provides an effective impact on the reservoir as a whole; exposure duration is selected experimentally.

 Thus, the excitation of a borehole acoustic emitter with a complex signal of a number of frequencies in the technological range ensures the processing of the near and far zones of the reservoir by high-frequency and low-frequency acoustic vibrations, which causes high efficiency in initiating various mechanisms for increasing the production rate of the well.

 A device for implementing the proposed method of acoustic processing of a well’s productive zone is performed on a known device containing a serially connected control device made on a master oscillator and a phase-pulse modulator, a generator device, a matching device, a cable, a borehole acoustic emitter, and also a power rectifier, the input of which is connected to terminals of the primary power supply network of the generating device, in the invention the generating device contains a number of key power amplifiers connected in parallel with the power buses to the power bus of the generator device and sequentially output buses to the output buses of the generator device, the master oscillator and the phase-pulse modulator are multi-channel, and the outputs of the channels of the master generator through the channels of the phase-pulse modulator are connected to the control inputs of the corresponding key power amplifiers of the generator device, and the control input of the multi-channel phase-pulse modulator is connected to the bus ulation voltage.

 The set of newly introduced blocks and connections in the proposed device allows to achieve the excitation of a borehole acoustic emitter with an electric signal in the form of the sum of the electrical signals of a number of frequencies in the technological range, which is necessary to affect the productive zone by fluctuations in the high frequencies of the technological range and low Raman differential frequencies.

 Thus, the proposed device fully provides the technical effect of the proposed method.

 The invention is illustrated in FIG. 1, 2. In FIG. 1 and 2 are structural diagrams of the device and timing diagrams, respectively. FIG. 2 illustrates timing diagrams of signals explaining the operation of the proposed device when it is performed according to a two-channel scheme.

 A device for implementing the proposed acoustic processing method (Fig. 1) comprises a control device 1, including an N-channel master oscillator 1.1 and an N-channel phase-pulse modulator 1.2, a generator 2, made on N key power amplifiers (KUM) 2.1 - 2.N , matching device 3, power rectifier 4, cable 5, downhole acoustic emitter 6.

 The control device 1 is designed to generate a series of pulsed signals (2N-signals) of the specified frequencies of the technological range (N frequencies), pairwise modulated by phase position, coming to the control of the corresponding CMC 2.1 - 2.N of the multi-channel generator device 2.

 The master oscillator 1.1 is designed to generate pulsed signals of a given series of frequencies of the technological range arriving at the inputs of the corresponding channels of the phase-pulse modulator 1.2. The channels of the phase-pulse modulator 1.2 can be performed according to the well-known scheme (9) and provide the conversion of the input signal of a given frequency into two pulse voltages, phase-shifted in proportion to the signal level on the control bus.

 The channels of the generator device 2, made on key power amplifiers 2.1 - 2.N, are implemented according to bridge circuits with a transformer output. KUM are designed for key gain in power of pulse signals of the corresponding frequency of the technological range, modulated in phase. The output signal of individual KUM channels is an alternating pulse voltage of the set frequency of the technological range, modulated by the duration of the pulses in accordance with a given phase shift.

 The total output signal of the generating device 2 is formed as a result of sequential addition of the output signals of the individual CMC channels and is a pulsed combined signal of a set number of frequencies of the technological range.

 Matching device 3 provides resonant filtering of the combined signal in the technological frequency range and matching the output of the generator device through cable 5 with the input of the downhole acoustic emitter 6.

 Power rectifier 4 is designed to convert the voltage of an industrial AC network 3ph 50 Hz 380 V into the supply voltage of the generating device. When implementing the KUM terminal stages on high-power high-voltage bipolar field-effect transistors (with a permissible voltage of more than 600 V), the power rectifier 4 can be made using a transformerless circuit on a three-phase diode bridge.

 Downhole acoustic emitter 6 is performed on cylindrical or rod piezoelectric transducers. The emitter provides the conversion of the combined electrical signal into acoustic vibrations.

 The proposed method is as follows.

 Acoustic well emitter 6 is lowered into the well to be acoustic treated to the bottomhole zone of the reservoir. This level is determined by the results of previous acoustic impact of geophysical surveys of the well. The control device 1 sets the level of acoustic power, taking into account the efficiency of the acoustic emitter and attenuation in the cable, carrying the signal frequency from the technological frequency range and frequency deviation. Perform acoustic exposure for 0.1 to 1 hour. As a result of this effect, a “buildup” of the productive zone occurs, accompanied by a primary “cleaning” of the near zone of the well, a change in temperature, primary micro-fractures, etc. Then, for 0.5 to 4 hours, an acoustic effect is performed with a combined signal, the spectral components of which are set in the technological frequency range of 10 - 60 kHz at Raman differential frequencies of 20 - 4000 Hz. In the same period, the spectral composition of the acoustic impact can be changed, while the combined signal can be formed from the beats of two frequencies with a deviation of one or both frequencies. With a combined acoustic impact, low-frequency signals arising in the medium, due to less attenuation, penetrate into the formation zones farther from the well, and additional physical mechanisms are excited whose reaction scales correspond to the scales of low-frequency excitation. Next, the cycle of acoustic exposure is repeated, moving the acoustic emitter 1 to 2 m below the previous position.

 The proposed device operates as follows.

 A multi-channel master oscillator generates a series of pulse signals of the corresponding frequencies of the technological range, which are fed to the inputs of a multi-channel phase-pulse modulator. Each frequency signal of the technological range is converted by the corresponding channel of the phase-pulse modulator into two pulsed signals of the meander type with a given phase shift. These signals are fed to the inputs of a key power amplifier, made, for example, according to a bridge circuit with a transformer output. As a result, an alternating voltage is formed in the diagonal of each KUM and, correspondingly, on its transformer output, the relative pulse duration of which is determined by the specified phase shift of the signals from the phase-pulse modulator, and the repetition frequency is equal to the frequency of the corresponding output signal of the output generator.

 The magnitude of the phase shift is proportional to the signal level on the control voltage bus, by changing which it is possible to control the relative pulse width of alternating voltage of the KUM channels. Accordingly, the actual value of the output voltage of the CMC changes and, therefore, the power level of the combined output signal of the generator device.

 Thus, a combined signal is generated on the output buses of a powerful generator device, with a spectrum corresponding to a number of frequencies of the technological range and representing the sum of the pulse voltages of individual KUM channels. In this case, a change in the signal level on the control voltage bus corresponds to a change in the total power of the combined signal.

 The principle of operation of the proposed device with a two-channel embodiment is illustrated by time diagrams (Fig. 3).

The output signals V ₁ and V _{2 of} individual key amplifiers KUM 2.1 and KUM 2.2, when sequentially added, are converted into the combined signal V. Frequencies f ₁ and f _{2 of} signals V ₁ and V ₂ differ by the difference frequency F = | f ₁ -f ₂ | , the value of which, as a rule, is not more than 0.1 - 0.2 of the average frequency of the signal of the technological range f = (f ₁ + f ₂ ) / 2. As a result, the total signal V is a beat signal of two frequencies of the technological range with a low-frequency envelope. The proximity of the frequencies f ₁ and f ₂ facilitates the filtering of their first harmonics in a matching device 3, which can be used with a conventional serial LC filter, while a quasi-sinusoidal beat signal V is generated at the input of the cable 5 and, respectively, at the inputs of the downhole acoustic emitter 6 _n with a given low-frequency envelope.

 As a result of a highly efficient linear conversion, the energy of the combined two-frequency signal is converted into the energy of radial acoustic vibrations of a number of frequencies in the technological range. During the propagation of such vibrations due to their nonlinear interaction in the medium in which the energy propagates, low-frequency acoustic vibrations are formed.

In the proposed device, the efficiency of the generator device reaches 90 - 95% with a specific power of the order of 300 - 500 VA / dm ³ .

 Good energy and weight and size characteristics of the equipment of the proposed device provide the convenience and efficiency of its use in expeditionary, landfill and industrial conditions of oil and gas fields.

The proposed method of acoustic processing, implemented on the basis of the claimed device, has been tested in the West Siberian region and in Belarus. Acoustic processing equipment of a new type was used to intensify and rehabilitate more than 50 inactive and low- and medium-rate oil wells. The obtained success rate was 70% with an average increase in flow rate of more than 50-60%, which distinguishes the proposed method from the known ones, the use of which provides a success rate of up to 50% with an average flow rate increase of 30-40%. When using the proposed method in the framework of testing a new type of acoustic processing equipment, in some cases an increase in flow rate was observed from 2 - 5 to 20 - 30 m ³ / day and from 20 - 30 to 60 or more m ³ / day. The aftereffect of the new method of acoustic processing ranged from 4 to 18 months. When using high-power acoustic emitting systems (up to 5 kW) in combination with the proposed processing method based on a new type of generator device, earlier inactive (from 1 to 5 years) wells were put into operation with an initial production rate of 10-30 m ³ / days, which confirms the high efficiency of the claimed technical solution.

Sources of information
1. Pechkov A.A., Shubin A.V. The results of work to increase the productivity of wells by the acoustic impact method. - Geoinformatics, 1998, N 3, 16 - 23.

 2. Kudinov V.I., Suchkov B.M. Methods for increasing well productivity. Samara: Samara Book Publishing House, 1996, 414 pp.

 3. Kuznetsov O. L., Efimova S. A. The use of ultrasound in the oil industry. - M: Nedra, 1983, 193 p.

 4. Gorbachev Yu. I. Physicochemical fundamentals of ultrasonic cleaning of oil wells. - Geoinformatics, 1998, N 3, 7-12.

5. Svalov A.M. On the mechanism of wave action on reservoirs. - Oil industry, 1996, N 7, 27 - 29
6. Patent of Russia N 20466936.

 7. Patent of Russia N 2026969.

 8. U.S. Patent No. 5,460,223.

 9. A.S. USSR N 1614110.

 10. RU N 95114542.

Claims (5)

 1. The method of acoustic processing of the productive zone of the well, based on the excitation of the borehole acoustic emitter with an electric signal of the technological frequency range, converting the energy of the electric signal into the energy of acoustic vibrations acting on the treated zone of the well at perforation intervals, characterized in that the excitation of the acoustic borehole emitter is formed in the form the sum of the electrical signals of a number of frequencies of the technological range, the acoustic vibrations of which are They act on the near productive zone of the well, and on the far productive zone of the well they are affected by low-frequency acoustic oscillations of the combination difference frequencies of the nonlinear interaction of acoustic oscillations of a number of frequencies in the technological range.  2. The method according to claim 1, characterized in that a number of frequencies of the technological range are selected in the frequency range of 10-60 kHz, taking into account the geophysical characteristics of the near productive zone of the well so that the Raman differential frequencies lie in the range of 20-400 Hz taking into account the geophysical properties of the far productive zone of the well.  3. The method according to p. 1, characterized in that the treatment of the productive zone of the well in the perforation intervals is carried out in increments of 1 to 2 m by a downhole acoustic emitter with an active base length of 0.5-1.5 m, acoustic power of 0.5-5 kW, and at each step, the downhole acoustic emitter is excited first by a tonal frequency-modulated electrical signal for 0.1 to 1 hour, and then by the sum of the electrical signals of a number of frequencies in the technological range for 0.5 to 4 hours.  4. The method according to one of claims 1 to 3, characterized in that as the sum of the electrical signals of a number of frequencies in the technological range, the sum of the electrical signals of two frequencies is selected, one of which is modulated in frequency.  5. A device for acoustic processing of a productive zone of a well, comprising a control device connected in series to a master oscillator and a phase-pulse modulator, a generator, a matching device, a cable, a borehole acoustic emitter, and a power rectifier, the input of which is connected to the terminals of the primary power supply network, and output - with the power bus of the generating device, characterized in that the generating device contains a number of key power amplifiers, included parallel to the power supply buses to the power supply bus of the generator device and sequentially output buses to the output buses of the generator device, the master oscillator and the phase-pulse modulator are multi-channel, and the channel outputs of the master generator are connected through the channels of the phase-pulse modulator to the control inputs of the corresponding key power amplifiers of the generator device, and the control input is multi-channel the phase-modulator is connected to the control voltage bus.

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