RU2584253C2 - Method for reactant-wave treatment of bottomhole formation zone with filtration pressure waves - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to methods of treatment of bottomhole zone of formations of wells and can be used in oil and gas industry. Method involves lowering to treated well interval equipment assembly on pipes with packer and valve devices and a jet pump. Treated well interval is isolated. Method includes wave treatment of bottomhole formation zone with filtration pressure waves by generating multi-cycle repression and depression on formation of adjustable amplitude and period. Method includes pumping chemicals into formation for treatment of bottomhole formation zone by pumping a calculated volume to pipes, adjustment to well bottomhole and forcing into process fluid into formation. Waiting for reaction of chemicals. Reaction products are pumped out from formation by creating depression and influx from formation. Control and registration of intake capacity, flow and pressure during treatment with determination of filtration parameters of bottomhole formation zone. Wave treatment is performed with generation in bottomhole formation zone of pressure waves simultaneously and at least in three frequency ranges. In sub infra-low frequency range generating filtration waves of first order with period of 1 to 2 hours. In sub infra-low frequency range generating filtration waves of second order with period of 0.01 to 0.1 hour. In low-frequency range generating third-order filtration waves with period of 0.0001 to 0.001 hour. First and second order waves are generated by generating multi-cycle repression and depression on formation in treated interval of well shaft with limitation of pressure of not more than permissible for cement ring and casing string. Waves of third and higher orders are generated by providing pulse shape pressure when generating multi-cycle depression and repression with steepness of fronts of not less than 0.1 MPa/s. Injection of chemicals and pumping of reaction products is performed at appropriate half-periods of waves of first order. Treatment of waves of second and higher orders is carried out at least while waiting for reaction of chemicals after chemical injection into formation. Generation of depression and repression on formation is carried out using circulation valve of multi-cycle action with a jet pump of insert type with supply of working pressure in pipe string.

EFFECT: technical result is intensification of oil recovery by increasing or restoration of water permeability of bottomhole formation zone.

5 cl, 3 dwg

Description

The invention relates to methods for processing bottom-hole formation zones (BHP) of wells and can be used in the oil and gas industry to intensify oil production by increasing the hydraulic conductivity of the bottom-hole formation zone.

The hydraulic conductivity coefficient is determined by three variables - permeability, effective (working) formation thickness and fluid viscosity. Accordingly, the reasons for the low hydraulic conductivity of the bottom-hole formation zone are: a) the low permeability of the bottom-hole zone of the formation due to its contamination with various deposits and (or) low permeability of the rocks composing the formation, b) high viscosity of the produced products and c) high layered formation heterogeneity in permeability, which reduces the effective formation thickness.

The depth of formation contamination occurring during the opening, operation, and repair process varies greatly between wells. For example, after the initial opening of the formation by drilling, its value may be 1 ... 2 m (Agliullin M.M. Estimation of the depth of penetration of the washout filtrate according to reservoir testers. // Assessment of the production and quality of the formation by the GIS methods / Tr. VNIIneftepromgeofizika /. - Ufa , 1988. - Issue 18. - S. 99-105). Most of all, this zone can reach up to ten or more meters in injection wells. The situation is exacerbated by an increase in the adhesion strength of pollutants to the rock in cases of a complex composition of muds and prolonged shutdown of the well.

The following reasons for the low hydraulic conductivity are the high viscosity of the produced products, the low permeability of the reservoir and its heterogeneity due to the maternal properties of the mineral skeleton and the fluids of the oil reservoir. The heterogeneity of the reservoir can be increased by the influence of well operating conditions and other external factors.

Due to the wide variety of reasons for the low hydraulic conductivity, a large arsenal of physicochemical methods of influencing the porous medium of the bottom-hole formation zone is used to ensure high-quality hydrodynamic communication between the well and the formation. The main is the chemical method (Ibragimov GZ, Fazlutdinov KS, Khisamutdinov NI The use of chemical reagents for the intensification of oil production, 1991). A wide variety of chemicals allows us to solve the problem of increasing and restoring the hydraulic conductivity of the bottom-hole formation zone with the effect on all variables. A common drawback of the method is the difficulty in injecting chemicals with hydraulic conductivity close to zero. In these cases, create a "bath" in the processed interval of the wellbore from the injected reagent and carry out additional physical effects on the formation with variable pressure. In practice, a wide frequency range from 10 ^-6 to 10 ⁶ Hz is used. In this case, the formation is exposed to elastic waves propagating through the formation at high speed - 1 ... 8 km / s and hydrodynamic or so-called. filtration pressure waves, accompanied by mass transfer of fluid in the radial direction from the well in a porous environment of the oil reservoir. The influence of filtration pressure waves is the main one and is carried out within a certain radius from the axis of the well, the magnitude of which depends on the oscillation frequency.

In the publication (Yanturin A.Sh., Rakhimkulov R.Sh., Kagarmanov N.F. Choice of frequencies with vibrational impact on the bottomhole formation zone. - Petroleum economy, 1986. - No. 12, - P. 40-42.) The influence of frequency on the radial depth of stimulation is shown. Ultrasonic waves with a frequency of 2 · 10 ⁴ ... 10 · 10 ¹⁰ Hz have an effective penetration depth of 1 ... 2 cm. Lowering the frequency to 20 ... 40 Hz increases the radial penetration depth and, accordingly, the impact on the formation to 1 ... 2.5 m. Translated to the volume of fluid in the near-wellbore rock, for example, with a porosity of 0.15 units, per 1 m of formation thickness for oil wells this will be 0.1 ... 0.75 m ³ / m. For deeper processing, the authors recommend an infra-low frequency range of 0.5 ... 5 Hz. The authors recommend a sub-low range of hydrodynamic pressure waves with a frequency of less than 0.5 Hz for exposure to a remote zone of the reservoir in order to increase oil recovery. These include cyclic injections with a cycle repetition rate of less than 2 · 10 ^-6 Hz, which corresponds to an oscillation period of more than 8 minutes.

The most famous and widely used method of processing the bottom-hole zone of the formation by creating high alternating pressure fluctuations (MPD) at the bottom of the well by pumping fluid from the wellhead.

The essence of the method lies in the fact that fluid is periodically pumped into the bottom-hole zone of the formation through tubing with the use of pumping units for a short time to reach acceptable injection pressures, which are then quickly discharged through the annulus (Abdullin F.S. Increasing well productivity. - M .: Nedra, 1975, p. 177).

When fluid is injected in the bottom-hole zone of the formation, existing or new cracks are opened, and when pressure is released, fluid flows from the formation to the bottom at a high speed. When alternating pressures are created, fatigue phenomena occur in the formation rocks and the possibility of formation and development of cracks appears, which leads to an increase in permeability of the bottom-hole zone. The method of variable pressure MPD can be successfully used for barodynamic, wave treatment of the reservoir. But the method is ineffective in case of deep formation mudding due to the rapid pressure equalization in the near-wellbore zone of the formation to the pressure in the well and, accordingly, an insignificant influx of liquid from the formation with contaminants. For this reason, it is applicable for shallow contamination of the formation. Also, the disadvantages of this method are the impossibility of selective treatment of the formation, the danger of damage to the cement ring, production casing when creating pressures that exceed permissible.

A known method of processing a productive formation (RU No. 2478778, 04/10/2013), which consists in a cyclically alternating operation of repression on the reservoir with the injection of technological fluids into the reservoir and depression on the reservoir with the inflow. At the same time, a wave action by elastic vibrations by a hydrodynamic generator installed in the well opposite the production interval is also carried out. Regulate the magnitude and / or rate of repression and depression in cycles. A regular wave action is controlled in terms of amplitude and frequency parameters. They monitor the development of filtration processes in the formation medium, decolmation and crack formation, on the basis of which control parameters, parameters of wave action by elastic vibrations in subsequent repression and depression cycles and the duration of these cycles in time are determined and assigned in the feedback mode. Moreover, the magnitude and / or rate of repression and depression in the cycles are regulated with their sequential increase. At the same time, their initial minimum values are determined and assigned depending on the filtration-capacitive parameters of the reservoir environment and at the same time periodically generate hydroshock pressure pulses in the well fluid. In one of the repression cycles, simultaneously with the wave action of elastic vibrations, compressible fluids are pumped into the formation medium to be treated, followed by their extraction when creating pulse depressions, while gas-liquid mixtures, oil-water emulsions, foams, and chemical reagents are used as compressible fluids.

The method performs wave processing of the bottom-hole zone of the formation by filtration pressure waves by creating multi-cycle repression and depression on the formation and elastic waves by a hydrodynamic wave generator and a device for creating hydroshock pressure pulses.

The disadvantage of this method is the complexity of the technical implementation. The complex of equipment launched to the bottom of the well must simultaneously create depression or repression on the formation, the work of a hydrodynamic wave generator and a device for creating hydroshock pressure pulses. In addition, the effective frequency range of hydrodynamic generators of elastic vibrations is limited from below to a frequency of tens of hertz and, accordingly, the radial depth of the formation does not exceed 1 ... 2 m.This factor complicates and makes the technological process of well treatment and achievement of the technological effect difficult, especially in cases of deep formation contamination.

A known method of hydrodynamic effects on the bottomhole formation zone (RU No. 2 483 200, 05/27/2013), including the descent into the well of the housing with a jet pump, isolation of the annular space from the internal volume of the tubing string above the roof of the reservoir, periodic change in the working flow direction fluid in the well to create depression cycles with repression, determining the volume of pumped fluid during depression and creating a hydraulic impulse to the reservoir during repression. In this case, the direction of flow of the working fluid in the well is changed during the controlled movement of the jet pump in the casing, the maximum depression is regulated, the period of repression is determined by the amount of fluid injected into the reservoir, and the periods of depression and repression are carried out at equal volumes of inflow and injected into the reservoir liquids in one cycle, the indicated volumes in each subsequent cycle increase. The cycles continue until the growth of fluid volumes ceases, then the chemical reagents are pumped into the formation, if necessary, the cycles are repeated, and the effect on the bottom-hole zone of the formation is completed during depression. Also, in the cycles of depression with repression, additional hydraulic impulses are generated, the energy of which is concentrated on the casing wall in the interval of the reservoir.

The disadvantage of this method is the difficulty of obtaining a technological effect when processing a highly contaminated low-permeability bottom-hole formation zone. Separate treatment of the formation, first by the physical method - pressure waves of depression and repression and then by the chemical - injection of chemicals, does not allow the synergistic mechanism of complex effects to appear and reduces the effectiveness of the method.

A known method of dynamic processing of the bottom-hole zone of high-temperature low-permeability reservoirs (RU, No. 2322578, 04/20/2008). The method provides for multiple sequential injection into the formation of acid composition and buffer fluids and a call inflow without holding the well to the reaction. The treatment is carried out in two or more cycles of injection and extraction of reagents, each time increasing the treatment radius by 40-70 cm, the injection is carried out in a hydro-pulse mode with an amplitude of hydroshocks on the formation of 2.0-10.0 MPa, and the inflow is called in the cyclic depression mode providing maximum formation productivity after each cycle of its processing.

The disadvantages of the method include a narrow area of its application, limited to high-temperature wells, acidic chemicals and the impact only on the mineral skeleton of the rock. Acid formulations can not always be used for processing, for example, on an old well stock at low injectivity, where there is often a risk of destruction of the cement ring by acid injected under high pressure. In these cases, solvents, surfactant solutions, deoxidizers and other reagents are recommended, with additional exposure to alternating pressure to enhance their destructive, dissolving effect on reservoir fluids and clogging substances, accelerate the process and complete development of the chemical reagent. In addition, in an analogue, operations are performed with control of the radius of treatment, the value of which depends on a large number of factors and cannot be used in practical processing of the well.

A known method of hydropercussion treatment of the bottom-hole zone of the formation and development of the well (RU, No. 2495998, publ. 10/20/2013), which includes isolation of the reservoir by a packer, injection of chemicals into the bottom-hole zone of the formation, waiting for the reaction, and treatment of the formation while waiting for the reaction to occur in a pulsed mode by creating cyclic pressure pulses of repression and depression on the formation with injection and pumping of formation fluid, pumping of reaction products after reaction and well development. In the process of reservoir processing, the injectivity during repression is controlled, the influx during depression, the pressure of the repression pulse is increased with a low slope of 1 ÷ 6 MPa / min, while the pressure of the repression and depression pulse is reduced, they provide a high slope of 1 ÷ 6 MPa / s, and the amplitudes of the pressure pulses do not exceed the permissible pressure on the reservoir, the duration of the repression pulse in the absence of injectivity is limited until the maximum permissible pressure is reached, in the presence of injectivity - until the volume of fluid is injected in an amount olee fluid volume in the area below the packer, the pulse duration of the depression in the absence of inflow operate equal repressionnogo pulse duration in the absence of pickup, if the influx - pumping fluid to a volume equal to the volume of injected fluid at repression.

The disadvantage of this method is to perform wave processing of the bottom-hole zone of the formation by filtration pressure waves by creating multi-cycle repression and depression on the formation only while waiting for the reaction of the chemical agent. Repetition of repression and depression operations with the aim of re-pumping a chemical agent and pumping out reaction products with the creation of pressure waves in the reservoir for a duration of 1 hour or more is not provided. This excludes the possibility of processing with layer-by-layer cleaning of the bottom-hole formation zone from contamination, for example, in cases of deep formation pollution. The pressure filtration waves in the process of waiting for the reaction have a relatively short duration and do not reach the next layer of the contaminated zone of the formation. For this reason, the method has a limitation for use in wells with deep formation mud, as well as for low permeability of the reservoir, high viscosity of products, where multiple reagent-wave treatment with waves of long duration and deep penetration into the formation is required.

The objective of the invention is the intensification of oil production by increasing or restoring the hydraulic conductivity of the bottom-hole formation zone by a complex reagent-wave action on the formation fluid, substances that pollute the bottom-hole zone and contain their rocks.

To do this, in the method of reactive-wave treatment of the bottom-hole formation zone with filtration pressure waves, which includes putting equipment layout on pipes with packer and valve devices and a jet pump, isolating the treatment interval of the well, wave processing of the bottom-hole formation zone by filtration pressure waves by creating a multi-cycle repressions and depressions on the reservoir of adjustable amplitude and period, injection into the reservoir of chemicals intended for processing formation zone by pumping the calculated volume into the pipes, adjusting it to the bottom of the well and pumping it into the formation with process fluid, waiting for the reaction of chemicals, pumping reaction products out of the formation by creating depression and causing inflow from the formation, monitoring and recording injectivity, flow and pressure in the processing process with the determination of the filtration parameters of the bottomhole formation zone, including by the method of filtration pressure waves for self-listening of wells, wave processing is carried out by creating pressure waves in the bottom-hole zone of the formation simultaneously and in at least three frequency ranges. In the sub-low-frequency range create first-order filtration waves with a period of 1 ... 2 hours. In the infra-low-frequency range create second-order filtering waves with a period of 0.01 ... 0.1 hours. In the low-frequency range create third-order filtration waves with a period of 0.0001 ... 0.001 hours. Waves of the first and second order are formed by creating multi-cycle repression and depression on the formation in the processed interval of the wellbore with a pressure limitation not more than that acceptable for the cement ring and casing, waves of the third and further orders are formed by providing a pulsed form of pressure when creating a multi-cycle depression and repression with the steepness of the fronts is not less than 0.0.1 MPa / s. Chemicals are pumped into the formation and reaction products are pumped out with the corresponding half-periods of first-order waves. Processing by waves of the second and subsequent orders is carried out, at least in the process of technological waiting for the reaction of chemicals after the injection of chemicals into the reservoir. At the same time, to create depression and repression on the formation, a multi-cycle action circulation valve with a plug-in jet pump with the supply of working pressure to the pipe string is used. For the technical implementation of the method, devices according to the RF patent for the invention No. 2495998 “Method for hydropercussion treatment of the bottomhole formation zone and development of wells and an ejector device for its implementation”, publ. 10/20/2013, bull. Number 32. The two variants of the device described in it contain two main units — a valve unit and a jet pump unit, the constructive solution of which allows us to solve the tasks. The main working elements of the valve assembly are a stem and a nipple with a radial channel between the in-tube and annular spaces.

In option 1, in the upper position of the rod, the radial channel is open and during the operation of the pumping unit for injection into the pipes, the fluid is directly circulated in the well, in the lower position, the rod overlaps the radial channel and the fluid injected into the pipes is pumped into the sub-packer zone and further into the reservoir. The rod is moved mechanically - from the wellhead through a pipe string attached to the rod, and the body is attached to the downstream packer.

In option 2, these operations are performed vice versa - in the upper position of the rod, the fluid injected into the pipes is pumped into the under-packer zone and into the reservoir, in the lower position, the fluid is directly circulated in the well. The rod is moved hydraulically by applying pressure to the pipes.

In the through axial hole of the hollow rod there are seats for installing the plug-in jet pump, which, if necessary, can be removed / installed during operation by reverse / direct liquid circulation along the pipe string. A jet pump with an open radial channel of the valve ensures the creation of depression on the formation; with a closed channel, repression is created on the formation by injected fluid passing through the nozzle of the jet pump into the sub-packer zone of the well.

Also, in the method for the reagent-wave treatment of the bottom-hole formation zone by filtration pressure waves prior to treatment, intervals of the well with a deteriorated hydrodynamic connection with the formation due to contamination of the bottom-hole zone of the formation are detected, the reagent-wave treatment of the bottom-hole zone of the formation is performed, and the estimated volume of chemical pumped into the formation at each wave the first order is determined based on the duration of the half-cycle and the obtained injectivity of the previous period, the flow of the chemical into the reservoir at each In the first stage, the first-order waves are carried out with the calculated volume of the process fluid equal to the volume of injected reagent for a given period plus the total volume of reagents injected into the reservoir for all previous periods, the second and subsequent orders are processed by waves of the first and second orders, and the wave treatment is performed until achieving the expected values of injectivity of the reservoir.

Also, in the method of reactive-wave treatment of the bottom-hole formation zone with filtration pressure waves, prior to treatment, intervals of the well with a deteriorated hydrodynamic connection with the formation due to the low permeability of the rocks composing the reservoir are detected, and, in the presence of geological and technological indications, the reagent-wave treatment of the bottom-hole zone of the formation is increased by pressure formation, and the filtration waves form with a stepped increase in the pressure of repression in increments of 3.0 ... 5.0 MPa, at each subsequent cycle of the wave per th order to achieve fracturing and acid compositions are used as chemical reagents.

Also, in the method of reactive-wave treatment of the bottom-hole formation zone with filtration pressure waves prior to treatment, intervals of the well, including objects with increased oil viscosity, are identified; the wave-bottom treatment of the bottom-hole zone of the formation is performed using compositions based on at least solvents and acids to form in the near-wellbore the zone of the reservoir channels, providing increased permeability of this zone.

Also, in the method of the reagent-wave treatment of the bottom-hole formation zone by filtration pressure waves, prior to treatment, borehole studies of the formation are carried out with the construction of a layer permeability profile and the section is divided into intervals differing in permeability. With a permeability variation of more than 50%, interval selective formation treatment is carried out, and the distance between the packers is set equal to the total thickness of a continuous sequence of intervals with a permeability variation of not more than 25%. Chemicals are injected into the bottom-hole zone of the formation, waiting for a reaction, creating cyclic depression and repression on the formation, and pumping out reaction products is performed at each processed interval of the formation isolated by packers. The permeability of the treated formation is leveled by means of a reagent-wave treatment of low-permeability intervals until the permeability variation of all intervals is less than 50%, and well development is carried out using a common filter.

The main difference between the method according to the invention is that the wave treatment is carried out by creating pressure filtration waves in the bottom-hole zone of the formation at the same time in at least three low frequency ranges. The use of low frequencies allows the formation to be processed at a sufficiently large radial depth. The presence of three or more frequency ranges of the sub-low-frequency, infra-low-frequency and low-frequency ranges and their simultaneous effect provides the maximum destructive effect on deposits throughout the contaminated zone of the formation. For full coverage by the action along the radial depth of the reservoir, the wave period of these ranges differs by an order of magnitude or more. In the sub-low-frequency range, first-order filtration waves are generated with a period of 1 ... 2 hours with an exposure depth of 10 or more meters. In the infra-low-frequency range, second-order filtration waves are generated with a period of 0.01 ... 0.1 hours with an exposure depth of up to 10 meters. In the low-frequency range, third-order filtration waves are created, with a period of 0.0001 ... 0.001 hours, the depth of which extends up to 1 m.

The relatively large period of the waves and the large difference between their ranges allows you to use the operation of pumping fluid into the reservoir and pumping out of the reservoir and, accordingly, the creation of repression and depression on the reservoir. These operations are used to create first and second order waves. At the same time, the pressure in the well is controlled to exclude violations of the cement ring and casing.

In the present method, when creating waves of the first and second orders, a multi-cycle depression and repression are carried out with a steepness of the pressure fronts of at least 0.1 MPa / s. The resulting shape of the pressure pulses in the wellbore, which is close to rectangular, provides pressure waves of the third and further orders in the formation. Their frequencies and amplitudes can be obtained by expanding the rectangular pressure pulses in a Fourier series according to well-known mathematical formulas (Fig. 2). As the order of the waves increases and their period of oscillation decreases, due to losses to overcome the hydrodynamic resistance of the constituent rocks, the radial depth of the effective impact on the formation decreases. The harmonic components of pressure waves of the third or more orders provide shock wave action at a small radius from the borehole wall of tens of centimeters, and the energy of these waves is entirely spent on the destruction and cleaning of deposits in the near-wellbore zone of the formation, which is most prone to mudding.

Waves of the first order, in addition to pressure effects on the remote zone of the formation, carry out the injection of chemicals into the formation and pumping of reaction products, respectively, into positive and negative half-periods of pressure. Multiple reagent-wave action on the formation by these waves allows to perform better treatment of the formation using various chemicals for the intended purpose. For example, in the first period of the first-order wave, use proppants to remove the clay component of the reservoir, in the second period, solvents to remove organic deposits in the reservoir, and in the third, acid compositions to dissolve the mineral skeleton of the rock and create new channels. In addition, it is possible to perform sequential layer-by-layer cleaning of the reservoir from contaminants throughout the radial depth of the contamination zone in small portions of the chemical agent at low formation injectivity.

The success of the method also increases due to the fact that the processing by waves of the second and subsequent orders is carried out, at least in the process of technological waiting for the reaction of chemicals after they are injected into the reservoir. The fluid in the bottomhole formation zone is subjected to the dynamic action of pressure waves. There is a reciprocal movement of the chemical in a porous medium. Under the pressure of repression, new channels and cracks are formed, where new portions of the chemical agent are extracted with each pulse, which are extracted during the subsequent depression. In conditions of poor filtration of the bottom-hole zone, the formation is maximally covered by the impact over its entire thickness. The reaction rate increases sharply, the processes of destruction and dissolution of pollutants or rocks are amplified. For example, the used acid compositions mainly affect the mineral skeleton of the rock, solvents destroy the structure of asphalt-resinous deposits, etc.

In addition, after creating highly permeable channels in the bottomhole formation zone, waves of the third and further orders, passing through these channels deep into the formation, have a reagent-wave effect on low-permeability layers. This increases the effective, working thickness of the treated interval of the formation and increases the hydraulic conductivity of the bottom-hole zone of the formation.

To determine the filtration parameters of the bottom-hole zone of the formation in the presence of instruments for recording pressure and fluid flow, the method of self-listening of wells by filtration pressure waves can be successfully used (RU, No. 2400622, September 27, 2010). The method allows determining the spatial distribution of reservoir hydrodynamic parameters with minimal cost depending on the distance to the well and revealing near-wellbore zonal heterogeneity of the formation by these parameters.

The method is most in demand for processing wells with poor hydrodynamic connection with the formation due to contamination of the bottom-hole zone of the formation, where it is difficult to sell the reagent into the formation. In this case, the reagent-wave treatment is performed by creating several first-order waves with sequential layer-by-layer cleaning of the bottom-hole formation zone from contaminants throughout the entire radial depth of the pollution zone in small portions of the chemical reagent. For this, the estimated volume of a chemical agent injected into the formation at each period of the first-order wave is determined based on the half-period duration and the received injectivity of the previous period. Then, the reagent is poured into the formation at each period of the first-order wave by the calculated volume of the technological fluid equal to the volume of injected reagent for this period plus the total volume of reagents injected into the reservoir for all previous periods.

The period of action of first-order waves is determined by the values of 1 ... 2 hours — the optimal time that ensures the effect of the filtration component of the pressure wave to a depth of 10 or more meters along the well radius. This time is the initial time for calculating the volume of the chemical reagent injected into the formation at each period, taking into account the injectivity measured in the previous period of the first-order wave. The wave treatment of the bottom-hole zone of the formation is carried out until the expected or required values of the injectivity of the formation are achieved. These values, as well as permissible pressure on the reservoir, are pre-determined and set by the geological service based on the results of the analysis of materials for the well.

Thus, a layer-by-layer cleaning of the bottom-hole formation zone is achieved with minimal time and guaranteed technological effect. This is also facilitated by the fact that the processing by waves of the second and subsequent orders is carried out during all cycles of processing by waves of the first order. The need for the latter is determined by the following.

When pumping chemicals into the reservoir with pumping units operating in constant output mode, there is a difficulty due to the mismatch of the minimum productivity of the injectivity pump at the permissible maximum pressure on the reservoir. If the injectivity of the formation is lower than this productivity, at first a certain volume of fluid is forced into the formation, the value of which is determined by the elastic-capacitive properties of the bottomhole formation zone. Then the reservoir is saturated and the pressure rises to the maximum permissible value and higher. In the present method, in order to eliminate the ultimate pressure on the formation in these cases, the reagents are forced into the formation in a pulsed mode by creating waves of the second and further orders. In addition, the dynamic injection mode with variable pressure on the formation leads to fatigue fracture of the rock, the formation of new channels and cracks and an increase in the injectivity of the formation at the stage of reagent transfer into the formation and to accelerate the processing process.

The depressive half-wave of the first-order wave ensures the removal of reaction products and mobile polluting particles from the formation. The volume of pumped fluid over a half-wave period is equal to the fluid injected into the formation, or slightly higher due to increased permeability of the formation. In the case of a deteriorated inflow and for a dynamic impact on the formation, the reaction products are also pumped out of the formation in a pulsed mode by creating waves of the second and further orders.

The most difficult are the treatment of wells with low permeability of the entire reservoir. In the present method, in order to provide high-quality hydrodynamic communication with a low-permeability formation, the effective diameter of the well is increased by forming many channels and voids in the near-wellbore zone of the formation.

To do this, in the presence of geological and technological indications, a reagent-wave treatment is performed with increased pressure on the reservoir, and the filtration waves form repression with a stepwise increase in pressure with a step equal to 3.0 ... 5.0 MPa, on each subsequent cycle of the first order wave until the hydraulic fracturing, and acid and other rock-destroying compositions are used as chemical reagents.

In contrast to the well-known acid hydraulic fracturing, the method is more effective due to fatigue fracture of the rock by alternating pressure pulses, removal of spent reagents, reaction products, destroyed and dissolved rock particles from the formation. This makes it possible to achieve crack formation at lower pressures and loads on the column and cement ring, use standard pumping units for repairing wells and tying the wellhead, and reduce the cost and speed up well processing.

The method also allows you to perform processing and stimulate oil production in wells operating geological objects with high oil viscosity. To do this, perform a reagent-wave treatment of the bottom-hole formation zone using compositions based on at least solvents and acids with the formation of channels in the near-wellbore zone of the formation that provide increased permeability of this zone. This will increase the flow area of viscous oil and increase its flow into the well.

Also, the method can be effectively used to increase the hydraulic conductivity of the formation by increasing the effective, working thickness of the formation. To do this, before processing, borehole studies of the formation are carried out with the construction of a layer-by-layer permeability profile, the section is divided into intervals that differ in permeability and, with a permeability variation of more than 50%, an interval selective treatment of the formation is performed. For this purpose, the distance between the packers is set equal to the total thickness of the continuous sequence of intervals with a permeability variation of not more than 25%, the injection of chemicals into the bottom-hole zone of the formation, the expectation of a reaction, the creation of cyclic depression and repression to the formation, and the pumping of reaction products are performed on each treated interval of the formation, isolated packers, and level the permeability of the treated formation by reagent-wave processing of low-permeability intervals to achieve a permeability variation Cex intervals of less than 50%, as well the development is carried out common filter.

In connection with the foregoing, we can conclude that the proposed proposal meets the criterion of "novelty." The applicant is not aware of technical solutions containing similar features that distinguish the claimed proposal from the prototype, which allows us to conclude that it meets the criterion of "inventive step".

In FIG. 1 shows a bottomhole pressure diagram of the technological process of reagent-wave processing of wells. No. 2473 of the Novo-Elkhovsky field.

FIG. 2 - diagrams of wave pressures of the third and further orders in the reservoir when decomposing the diagrams of depression and repression in the wellbore according to the Fourier series.

FIG. 3 is a diagram of the pressure of waves of the second order in the process of waiting for the reaction of the technological process of the reagent-wave processing of wells. No. 2473 of the Novo-Elkhovsky field.

The method is implemented as follows, using the example of a reagent-wave treatment of injection well No. 2473 of the Novo-Elkhovsky field. The well was drilled in 1980, 1 year before the SCR was inactive, the perforation interval was 1822.8-1825.6 m in the Kyn horizon Do.

According to the geological service of NGDU, the throttle response before stopping the well was Q = 13 m ³ / day at a pressure of P = 95 atm, expected values after treatment Q = 70 m ³ / day at P = 95 atm, allowable pressure on the formation and production string during processing Rdop. = 105 atm.

At the well, killing, lifting of underground equipment, repair of the production casing, preparatory work for lowering and installing the packer, and determination of the tightness of the production casing were performed. On technological tubing tubing NKT-73 mm, a packer was lowered into the well with a liner and a multi-cycle action circulation valve installed above, modified for landing in the through channel of an insert jet pump (according to RU patent, No. 2495998, published on October 20, 2013). An autonomous pressure gauge was installed under the packer in the tubing. The packer was planted at a depth corresponding to the bottom of the shank, the lower mark of the machined perforation interval of -1826 m (section 2, Fig. 1). The wellhead was sealed with a preventer with central and annular valves. The injectivity of the formation was determined by pumping the process fluid with the pump unit — the well does not accept at a pressure of P = 130 atm. The rate of pressure drop was 105-0 = 105 atm for 20 min (section 3, Fig. 1). Estimated acceleration during cyclic prodavke is about 1.0 m ³ / h.

Next, a multi-cycle reagent-wave treatment of the formation was performed. To do this, the plug-in jet pump was dropped into the pipe string, the pump was installed by pumping the process fluid into the seat of the circulation valve. The valve design provides two pump operation modes. At a low gear of the pumping unit, the valve is closed and fluid is pumped through the pump nozzle into the sub-packer zone of the well with repression to the formation. With an increase in the flow rate, the valve opens and the jet pump is turned on, creating a depression on the formation. Mode switching is carried out by changing the engine speed of the pump unit CA-320 or gear shifting.

Consider the operations of the first stage of work corresponding to the first period of the first-order wave of the sub-low-frequency range (section 3-7, Fig. 1). First, we determined the volume of the chemical reagent (PAX acid composition), which can be pumped into the reservoir for a half-period of the first-order wave of the sub-low-frequency range - 0.5 ... 1 hour. Estimate pickup volume at 1 m ³ / h was 0.5 ... 1.0 m ³ at a pressure of 105 atm.

The estimated volume of the chemical reagent - 0.5 m ^{3 was} pumped into a deflated pipe string, brought to the bottom in the sub-packer zone of the well with the estimated volume (5.1 m ³ ) of the process fluid (section 4, Fig. 1). The chemical reagent was pushed into the reservoir with the estimated volume of the process fluid (0.5 m ³ ), equal to the volume of the injected reagent in the half-period of the repressive action by the first-order wave. Due to the lack of injectivity, the reagents were pushed into the formation in a pulsed mode with the creation of second and further orders of the infra-low-frequency range in the formation of the filtration waves with a period of 0.01 ... 0.1 hours. After the chemical was sold, reagent-wave treatment of the formation was carried out by waves of the second and further orders by creating multi-cycle repression and depression on the bottom of the well for a period of 0.01 ... 0.1 hours with a pressure limit of not more than 105 atm (section 6, Fig. 1). The duration of the operation was limited by the waiting time for the reaction, equal to 2 hours, regulated by the governing documents for the chemical used.

After treatment with second-order waves, a negative half-period of first-order waves was created in the formation by pumping liquid from the formation with the formation of depression on the formation (section 7, Fig. 1). Pumped out 1.5 m ^{3 of} well fluid and reaction products. The injectivity was determined - by the rate of pressure drop, which amounted to 105-0 = 105 atm in 8 minutes, by the injectivity in the cyclic mode - 1.5 ... 2.0 m ³ / h.

Next, the second stage of work was performed, corresponding to the second period of the first-order wave of the sub-low-frequency range (section 9-13, Fig. 1). At the same time, the calculated volume of 1.5 m ³ was pumped into the pipes of the GKK clay-acid composition based on the half-life (1 hour) and the injectivity of the previous period (1.5 m ³ / h). This portion of the reagent was brought by the calculated volume of the process fluid (4.1 m ³ ) into the sub-packer zone of the well and pushed into the reservoir by the estimated volume of the process fluid (2.0 m ³ ), in accordance with a method equal to the volume of the injected reagent (1.5 m ³ ) plus the total volume of fluid injected into the reservoir in previous periods (0.5 m ³ chemical reagent).

In the process of waiting for the reaction, a reagent-wave treatment was performed by waves of the second and further orders in cycles of 10 minutes for 1.5 hours, the creation of a depression half-wave and pumping of the reaction products in a volume of 4.5 m ³ during the half-cycle of its action. Determined the injectivity of the reservoir (section 13, Fig. 1), which amounted to 72 m ³ / day at a pressure of 105 atm.

Thus, the reagent-wave processing achieved the expected injectivity over 2 periods of 1.5 hours of first-order waves, ~ 20 periods of 5 ... 10 minutes of second-order waves with the creation of ~ 60 periods of 1 ... 3 minutes of third-order waves and t, respectively .d.

In a similar way, more than a hundred wells were processed in the fields of Tatarstan in the process of their overhaul. The treatment was mainly carried out on injection wells, where there was no injectivity due to reservoir clogging - during the injection of water or during the repair of the well and there was no possibility of selling acids and other chemicals into the formation. The technological success of the treatments, which was determined by the activated measurements of the injectivity of the wells before and after the SCR with the injection into the reservoir of 6 m ^{3 of the} process fluid upon reaching the injectivity, was 100%. The geological success of overhaul with an SCR at the final stage of well repair by the method of the present invention was 74% (according to field measurements 3 months before and 1 month after overhaul of 35 wells of the injection fund of Elkhovneft Oil and Gas Production Unit).

The technical and economic effect of the method consists in a high degree of adaptation of technology and technical means to standard technologies for well repair, a wide range of applications in various geological conditions. The method provides a guaranteed increase in the productivity of the treated wells to the expected values, the possibility of obtaining a technological effect in the wells, complicated by both deep mudding and contamination of the bottomhole formation zone, and with low permeability, high reservoir heterogeneity and high viscosity of the produced products.

Claims (5)

1. The method of reagent-wave treatment of the bottom-hole formation zone with filtration pressure waves, including the descent of the equipment layout on pipes with packer and valve devices and a jet pump, isolation of the treatment interval of the well, wave treatment of the bottom-hole formation zone by pressure filtration waves by creating multi-cycle repression and depression on the formation of adjustable amplitude and period, the injection into the formation of chemicals intended for processing the bottom-hole zone fins by pumping the calculated volume into pipes, adjusting it to the bottom of the well and pumping it into the formation with process fluid, waiting for the reaction of chemicals, pumping reaction products out of the formation by creating depression and causing inflow from the formation, monitoring and recording injectivity, inflow and pressure during processing with determination of the filtration parameters of the bottomhole formation zone, including according to the method of filtering pressure waves for self-listening of wells, characterized in that the wave treatment is carried out by creating pressure waves in the bottom-hole zone of the formation simultaneously and at least in three frequency ranges, in the sub-low-frequency range, first-order filtering waves are generated for a period of 1 to 2 hours, in the infra-low-frequency range create filter waves of the second order with a period from 0.01 to 0.1 hours, in the low frequency range create filter waves of the third order with a period from 0.0001 to 0.001 hours, waves of the first and second order are formed by creating multi-cycle repression and depression on the formation in the processed interval of the wellbore with a pressure limit not exceeding the allowable for the cement ring and casing, waves of the third and further orders are formed by providing a pulsed form of pressure when creating a multi-cycle depression and repression with the steepness of the fronts is not less than 0.1 MPa / s, chemical reagents are pumped into the formation and reaction products are pumped out at the corresponding half-periods of first-order waves, processing olnami second and subsequent orders carried out at least during the process chemicals after the response standby chemical injection into the formation and to create a depression and repression on the layer using multicycle circulating valve with jet pump action of the plug-type supply working pressure in the pipe string. 2. The method of reagent-wave treatment of the bottom-hole formation zone by filtration pressure waves according to claim 1, characterized in that prior to treatment, intervals with impaired hydrodynamic connection with the formation due to contamination of the bottom-hole zone of the formation are detected, and the reagent-wave treatment of the bottom-hole zone of the formation is performed, the estimated volume being the chemical agent injected into the formation at each period of the first-order wave is determined on the basis of the half-cycle duration and the obtained injectivity of the previous period, the flow of the chemical into the formation on each period, first-order waves are carried out with a calculated volume of technological fluid equal to the volume of injected reagent for a given period plus the total volume of reagents injected into the reservoir for all previous periods, processing by waves of the second and subsequent orders is carried out during all cycles of processing by first-order waves and wave processing produce until the expected values of injectivity of the reservoir. 3. The method of reagent-wave treatment of the bottom-hole zone of the formation by filtration pressure waves according to claim 2, characterized in that prior to treatment, intervals of the well with poor hydrodynamic connection with the formation are identified due to the low permeability of the rocks composing the reservoir and, in the presence of geological and technological indications, reagent-wave treatment of the bottom-hole zone of the formation with increased pressure on the formation, and the filtration waves form repression with a stepwise increase in pressure with a step equal to from 3.0 to 5.0 MPa for each further short cycle wave of the first order to achieve fracturing and acid compositions are used as chemical reagents. 4. The method of reagent-wave treatment of the bottom-hole formation zone with filtration pressure waves according to claim 2, characterized in that prior to treatment, well intervals are identified that include objects with increased oil viscosity and the reagent-wave treatment of the bottom-hole formation zone is performed using compositions based on a minimum of solvents and acids with the formation of channels in the near-wellbore zone of the formation, providing increased permeability of this zone. 5. The method of reagent-wave treatment of the bottom-hole formation zone with pressure filtration waves according to claim 1, characterized in that prior to the treatment, downhole studies of the formation are carried out with the construction of a layer-by-layer permeability profile, the section is divided into intervals differing in permeability and, with a permeability variation of more than 50% perform interval selective treatment of the formation, and set the distance between the packers equal to the total thickness of a continuous sequence of intervals with a permeability variation of not more than 25%, the injection of chemicals into the bottom-hole zone of the formation, waiting for a reaction, creating cyclic depression and repression on the formation and pumping out reaction products is performed on each processed interval of the formation isolated by packers, and the permeability of the treated formation is leveled by means of the reagent-wave treatment of low-permeability intervals until the permeability variation is achieved of all intervals less than 50%, and well development is carried out by a common filter.

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