RU2750770C1 - Method for activating permeability of rocks in development of fluid deposits - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: invention relates to the oil industry and can be used for mining through boreholes after hydraulic fracturing and increasing the permeability of rocks in macro-volumes in the near-wellbore space. A method for activating the permeability of rocks during the development of fluid fields is proposed, which consists in placing on the surface of equipment for controlling the parameters of a resonant wave device, immersing a resonant wave device in the well to create an oscillatory process of a given frequency in the infrasonic, ultrasonic and high-frequency frequency ranges in the processed oil fluid in the area of oil production, and modulation of radiation pulses by resonant pulses of hydrocarbons of the processed oil fluid with the formation of standing waves. At the same time, to intensify the decrease in the viscosity of the processed oil fluid in the acoustic field by changing the thermodynamic state by partial heating - due to the absorption of elastic energy and the breaking of bonds in individual macromolecules of the processed oil fluid, and - destruction of rigid structural bonds of the clay-sand fraction during cavitation - the radiation intensity at infrasonic and high-frequency radiation frequency ranges should be at least 2 W/cm², and under ultrasonic exposure - at least 10 W/cm², depending on the ratio of the viscous component of the processed oil fluid, solutions and clay-sand fraction. Wherein the time of exposure to radiation for the intensification of cavitation is carried out considering the temperature and pressure conditions in the well at the level of the formation being exposed, and ranges from 5 to 20 minutes. At the same time, by means of an automatic control system, including sensors of the dynamic properties of the medium, by means of a numerical software device, the parameters of the operation of the generators are controlled.

EFFECT: invention increases the technological and operational efficiency of the hydrocarbon production process.

1 cl, 1 dwg

Description

The invention relates to mining, the oil industry and can be used for mining through boreholes after hydraulic fracturing and increasing the permeability of rocks in macro-volumes in the near-wellbore space.

Known geotechnological complexes of borehole hydraulic production with ultrasonic initiation, used for the disintegration of high-clay sands of gold-bearing placers in a combination of mechanical and ultrasonic effects [1-2].

However, solving the problem of softening and stability during the transition of a rock from a brittle to a plastic one and from a structured to a structureless state in a slurry requires a complex and long-term wave action to maintain the stability of the structureless state.

The known method of hydraulic fracturing, including the use of a downhole pulsator to improve the convection of fluids in the fracture and conglomeration of portions of proppant - proppant [3].

The disadvantages of this method are the low intensity of oscillations of the pulsator, which is regulated in a narrow range of changes, and the reliability of operation of mechanisms for regulating the intensity of oscillations.

Known methods of inhibiting undesirable phenomena during the development of oil fields using ultrasonic radiation in the frequency range from 15 kHz to 50 kHz and subsequent additional exposure to the fluid by electromagnetic fields [4].

The disadvantages of these methods are their local and depth-limited impact in the process of fluid supply.

Known devices for hydraulic fracturing using structural elements for the implementation of an electric discharge, initiating a water hammer in the well [5], as well as methods for intensifying oil production using sound vibrations of low frequencies and high frequencies of the ultrasonic range, which are produced by an acoustic resonator-sound generator placed on bottomhole [6] and - electromagnetic resonance effect on the productive formation, in which, using resonant wave generators located on the surface or submerged in the well, electromagnetic oscillations are created in the productive formation, which impose on the natural frequency of hydrocarbon fluid oscillations, forming resonant electromagnetic oscillations, and control the resonant oscillations using the equipment placed on the surface [7].

The disadvantages of these methods are complex technological processes and high costs for the implementation of hydraulic fracturing.

A known method of treatment of the bottomhole formation zone, including lowering the pipes to the bottom, pumping the treatment composition through them, lifting the pipes to the surface, lowering them into the well and placing an ultrasonic wave emitter against the treated interval of the formation and treating the formation with ultrasound in the medium of this composition. Before the treatment of the formation, the casing is perforated in the interval of the productive formation in the medium of the processing composition, the ultrasonic treatment of the formation is carried out when the processing composition enters the formation, and then from the formation into the well [8].

This method does not take into account the characteristics of the rock saturated with the treated composition, its plasticity, the content of the clay component with the fluid during the ultrasonic treatment of the formation.

The closest in technical essence is a method of influencing the fluid of oil fields during oil production, which consists in immersing a resonant wave device into the well and creating an oscillatory process of a given frequency in the processed oil fluid in the oil production zone. The resonant-wave device is immersed in one of the wells of the treated area, and movable resonant modules, waveguides and contours are placed on its surface, the oscillatory process is carried out directly in the processed oil fluid by carrier electromagnetic waves in the frequency range 3⋅10 ^-5 to 3⋅10 ¹⁴ Hz or ultrasonic waves in the frequency range from 1.5⋅10 ⁴ to 10 ⁹ Hz, or acoustic waves in the frequency range from 17 Hz to 20 kHz, which modulate information signals, resonant hydrocarbons of the processed oil fluid, and form into standing waves. An acoustic field with an intensity of 8-10 kW / m ² (which means 0.8-1 W / cm ² ) with a frequency of 18-25 kHz is used [9]. The analogue also includes information containing explanations to clarify the reasoning for the use of physical impact on the processed environment. It is noted that the value of the wave field intensity required to influence the medium depends significantly on its initial thermodynamic state.

This method also does not take into account the relative mass characteristics of the composition of the rock with fluids, solutions and proppants when exposed to the infrasonic, ultrasonic and high-frequency ranges of frequencies.

The technical result of the proposed method is to increase the technological and operational efficiency of the hydrocarbon production process by initiating the formation permeability and hydraulic fracturing by activating actions on the zone of a fluid-saturated formation in the infrasonic, ultrasonic and high-frequency frequency ranges, taking into account the determination of rational parameters of radiation intensity leading to the formation of cavitation hydrodynamic effects in liquid environments that activate fluid mobility and destruction of rigid structural bonds of fluid-saturated rocks.

The technical result is achieved due to the fact that in the method of activating the permeability of rocks during the development of fluid deposits, which consists in placing equipment on the surface to control the parameters of a resonant wave device, immersing a resonant wave device in the well to create an oscillatory process of a given frequency in infrasonic, ultrasonic and high-frequency frequency ranges in the processed oil fluid in the oil production zone, modulating radiation pulses by resonant pulses of hydrocarbons of the processed oil fluid with the formation of standing waves, to intensify the decrease in the viscosity of the processed oil fluid in the acoustic field by changing the thermodynamic state by partial heating - due to the absorption of elastic energy and the breaking of bonds in individual macromolecules of the processed oil fluid, and - destruction of rigid structural bonds of the clay-sand fraction during cavitation - intensively the radiation intensity at infrasonic and high-frequency ranges of radiation frequencies should be at least 2 W / cm ² , and at ultrasonic exposure - at least 10 W / cm ² , depending on the ratio of the content of the viscous component of the processed oil fluid, solutions and clay-sand fraction, and the time of exposure to radiation to intensify cavitation is carried out taking into account the temperature and pressure conditions in the well at the level of the reservoir being exposed and is from 5 to 20 minutes, while by means of an automatic control system, including sensors of the dynamic properties of the medium, the parameters of the generators are controlled by means of a numerical program device.

The ability to form the required sequence of actions performed by the proposed means allows you to solve the problem, determines the novelty, industrial applicability and inventive level of development.

FIG. 1 - General view of the section of the implementation of the method.

The method is performed using equipment 1, located on the surface 2. Equipment 1 includes an automatic control system 3 with a numerical programmer 4, generators 5, a resonant-wave device 6 and sensors 7 of the dynamic properties of the medium. The resonant-wave device 6 and sensors 7 are placed in the well 8 to influence the processed oil fluid 9 at the level of the formation 10 in the zone 11 for oil production.

The method of activating the permeability of rocks during the development of fluid deposits is carried out as follows.

The equipment 1 is placed on the surface 2 to control the parameters of the resonant-wave device 6 and the resonance-wave device 6 is immersed in the well 8. To create an oscillatory process of a given frequency in the infrasonic, ultrasonic and high-frequency frequency ranges in the processed oil fluid 9 in the production zone 11 oil, the radiation pulses are modulated by resonant pulses of hydrocarbons of the processed oil fluid 9 with the formation of standing waves. To intensify the decrease in the viscosity of the processed oil fluid 9 in an acoustic field by changing the thermodynamic state by partial heating - due to the absorption of elastic energy and breaking bonds in individual macromolecules of the processed oil fluid, and - destruction of rigid structural bonds of the clay-sand fraction during cavitation - the intensity of radiation during infrasound and high-frequency ranges of radiation frequencies should be at least 2 W / cm ² , and under ultrasonic action - at least 10 W / cm ² , depending on the ratio of the content of the viscous component of the processed oil fluid, solutions and clay-sand fraction. The time of exposure to radiation for the intensification of cavitation is carried out taking into account the temperature and pressure conditions in the well at the level of the formation 10, which is exposed to the action and is from 5 to 20 minutes. By means of an automatic control system 3, including sensors 7 of the dynamic properties of the medium, by means of a numerical program device 4, the operating parameters of the generators 5 are controlled.

The proposed method for activating the permeability of rocks during the development of fluid deposits will increase the technological level of mineral extraction, improve the performance of the complex maintenance, and increase the profitability of production and environmental safety.

Information sources

1. Patent RU No. 2272139, E21C 45/00, publ. 03/20/2006.

2. Patent RU No. 2272140, E21C 45/00, publ. 03/20/2006.

3. Patent RU No. 2563901, E21B 43/267, E21B 34/10, publ. 09/27/2015.

4. Patent RU No. 2694329, E21B 37/00, publ. 11.07.2019.

5. Patent RU No. 2412346, E21B 43/26, E21B 47/01, publ. 02/20/2011.

6. Patent RU No. 2133332, E21B 43/00, E21B 43/25, publ. July 20, 1999.

7. Patent RU No. 2379489, E21B 43/16, publ. 20.01.2010.

8. Patent RU No. 2108452, Е21В 43/25, publ. 04/10/1998.

9. Patent RU No. 2281387, E21B 43/16, publ. 10.08.2006.

Claims (1)

A method for activating the permeability of rocks during the development of fluid fields, which consists in placing equipment on the surface for controlling the parameters of a resonant wave device, immersing a resonant wave device in the well to create an oscillatory process of a given frequency in the infrasonic, ultrasonic and high-frequency frequency ranges in the processed oil fluid in the zone of oil production, modulation of radiation pulses by resonant pulses of hydrocarbons of the processed oil fluid with the formation of standing waves, characterized in that to intensify the decrease in the viscosity of the processed oil fluid in the acoustic field by changing the thermodynamic state by partial heating - due to the absorption of elastic energy and breaking of bonds in individual macromolecules of the processed oil fluid, and - destruction of rigid structural bonds of the clay-sand fraction during cavitation - radiation intensity during infrasonic and high-frequency ranges of radiation frequencies should be at least 2 W / cm ² , and under ultrasonic exposure - at least 10 W / cm ² , depending on the ratio of the content of the viscous component of the processed oil fluid, solutions and clay-sand fraction, and the time of exposure to radiation for intensification Cavitation is carried out taking into account the temperature and pressure conditions in the well at the level of the affected formation, and is from 5 to 20 minutes, while by means of an automatic control system including sensors of the dynamic properties of the medium, the parameters of the generators are controlled by means of a numerical software device.

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