The proposed invention relates to the oil and gas industry as well as water utilization system, and specifically, to methods for restoring the well productivity and devices for cleaning a filter under the downhole conditions.
Since the well productivity (specific yield) decreases over time due to clogging of the mesh filter and surrounding gravel pack with various types of colmatants (contaminants), it becomes necessary to perform an unscheduled well shutdown for a periodic cleaning of the filter and pre-filter zone of the well.
An acoustic method of filter decolmatation is known, which utilizes magnetostrictive or piezoelectric ultrasonic emitters (V. S. Alekseev and V. G. Grebennikov, Restoring an Output of Water-supply Wells [in Russian], Agropromizdat, Moscow (1987), p. 156). The method provides a wide range of emitted oscillation frequencies and the ability to generate a high-energy liquid cavitation flow, which allows destroying various types of colmatants. In addition, transmission of ultrasonic vibrations creates a disinfecting effect and allows suppressing the growth of biological organisms in a liquid medium. The disadvantage of this method is the need to dismantle the water-lifting equipment every time the well productivity decreases to a critical level.
A method and device for cleaning a pre-filter zone of the vertical water-supply wells are known, which do not require dismantling the water-lifting equipment (RF Patent 2612046-prototype). The well design represents a casing string, the lower portion of which contains a pre-filter zone in the form of a slot-type mesh filter, while the external space around the filter is filled with a gravel pack. Located inside the casing string is water-supply equipment consisting of a pipeline for pumping water with a submersible pump installed at the end thereof above the filter level. The device comprises an acoustic emitter and lifting equipment for delivering thereof to the inner space of the filter, which are respectively connected via an electric cable with a control panel of the lifting equipment and high-frequency electric oscillator. Both the control panel and electric oscillator are located above ground. The lifting equipment is mounted on the lower portion of the submersible pump and causes the acoustic emitter to perform reciprocating movements (up and down) along the axis of the downhole filter. Such method allows performing regular cleaning of the pre-filter zone of the well at any suitable point of time.
An acoustic emitter comprises a chain of interconnected sectors (blocks) located along the filter axis and made of waterproof cylindrical housings, the axes of symmetry of which are perpendicular to the filter axis. Installed inside each housing are two ultrasonic vibration systems, which operate based on the use of piezoelectric (piezoceramic) or magnetostrictive transducers converting electric oscillations into mechanical. The working surfaces of the waveguide tools (sources of ultrasonic vibrations) are oriented in the opposite directions toward the inner surface of the filter. The axes of symmetry of the blocks are located relative to each other at an angle determined by dividing 180° by the number of such blocks (fan-shaped style). Depending on the area of the working surface of the waveguide tool and, hence, the size of the ultrasonic flow projection (from one source) onto the inner surface of the filter, the number of installed blocks is selected such that by moving the acoustic emitter, the total ultrasonic flow (from all sources) would cover the entire inner surface of the filter. A chain of blocks in the form of a string is secured along the axis of the filter using two sets of bracing elements in the form of flexible centering rods arranged in a fan-shape fashion perpendicular to the filter axis in the upper and lower portions of the string.
The disadvantage of such acoustic emitter has to do with the fact that in case of a small inner diameter of the downhole filter, only small-sized ultrasonic vibration systems with limited working surface of the waveguide tool can be used. Such ultrasonic vibration sources have small projected dimensions of ultrasonic flow onto the filter, which requires a large number of ultrasonic transducer blocks and, hence, significantly complicates the design of the acoustic emitter.
The objective of the proposed invention is to eliminate the disadvantages of the prototype, while solving the following tasks:
The technical result is achieved by using a single ultrasonic transducer block with supporting plates, a rotary unit, and an electric motor installed in the upper and lower sections thereof. The device is embodied as a string assembled of the following sequentially interconnected components: an upper supporting plate, a rotary unit, an ultrasonic transducer block, an electric motor, and a lower supporting plate. The supporting plates are located perpendicular to the filter axis and have bracing elements arranged around the perimeter. The electric motor is used to facilitate rotary oscillations of the ultrasonic transducer block within a 180-degree range, similar to a clock pendulum, while the ultrasonic fluid flows from the working surfaces of the waveguide tools sweep the inner surface of the filter within a 360-degree range. Concurrently with this process, the delivery means causes the acoustic emitter to perform reciprocating movements along the axis of the filter. Thus, the successive treatment of the entire inner surface of the downhole filter with ultrasonic fluid flows is enabled along with regular cleaning of the pre-filter zone of the well without dismantling the water-lifting equipment.
As an example, an ultrasonic vibration system having high amplitude of vibration (see RF patent 2465071) is used as an ultrasonic transducer. The vibration system is shaped as a rotary body and comprises at least two disk-type piezoelectric elements, located between the reflecting and concentrating plates, and a disk-shaped waveguide tool mounted at the end of the body.
The invention is illustrated by the drawings (
In the embodiment of the invention, used as an example, high-capacity ultrasonic vibration systems with high amplitude of vibrations require the use of the large-diameter disk-type piezoelectric elements, which results in an increase in the overall dimensions of the vibration system as a whole. In order to be placed within an acoustic emitter, the ultrasonic transducer block (
As an example,
In addition to the parts shown under the same numbers as in
The proposed device operates as follows.
Once ultrasonic vibration systems (17) are activated, disk-shaped waveguide tools (5) generate two oppositely oriented ultrasonic fluid flows (cone-shaped) directed at the inner surface of filter (6), which form thereon circular projected sections (diameter—D) of ultrasonic vibration impact (see
In order to optimize the filter cleaning procedure using the proposed device, the frequency and power of ultrasonic vibrations should first be determined. The extensive experimental testing has shown that to ensure good cleaning of the slot-type filters and gravel pack of the pre-filter zone of the well, the following operating parameters of the ultrasonic transducers are selected as an option: power density—ranging from 8 to 12 W/cm2, vibration frequency—from 17 to 25 kHz (the most preferable is a resonant frequency of about 20 kHz). In addition, a minimum time (T) of effective exposure to ultrasonic fluid flow required to destroy a certain type of colmatants, and diameter (D) of the flow projection onto the inner surface of the filter (diameter—Df) are determined. Based on these values and sweeping conditions of the entire inner surface of the filter with ultrasonic flow, the following options of the pre-filter zone cleaning procedure are selected:
To clean the filters of inclined and horizontal wells, any other delivery means can be used, which moves the acoustic emitter within the filter space, such as a device described in RF Patent 2382178, comprising an electric motor with hydraulic propulsion.
This device allows performing acoustic and chemical cleaning of the filter at the same time by pumping cleaning fluid into the well. An ultrasonic disinfection of the pre-filter zone is also performed. After cleaning the pre-filter zone, contaminated water is pumped out to be subsequently cleaned under the above-ground conditions.
Thus, the proposed technical solution of the acoustic emitter device has the following advantages compared to the prior art:
The invention is industrially applicable.
Number | Date | Country | Kind |
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RU 2018 04161 | Feb 2018 | RU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/RU2018/000812 | 12/12/2018 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/151895 | 8/8/2019 | WO | A |
Number | Name | Date | Kind |
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5727628 | Patzner | Mar 1998 | A |
20140301164 | Mandal | Oct 2014 | A1 |
20160076340 | Abramova et al. | Mar 2016 | A1 |
Number | Date | Country | |
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20210039143 A1 | Feb 2021 | US |