RU2275495C1 - Method and device for reagent and impulse well and productive bed treatment - Google Patents

Abstract

FIELD: oil production industry, particularly for well bottom cleaning.

SUBSTANCE: method involves supplying active liquid medium through pressure booster; applying impulse action to liquid medium; supplying active liquid medium into jet means nozzle and extracting passive liquid medium from formation zone. The active liquid medium is mixture including aliphatic and aromatic hydrocarbon solvents to which treated demulsifier is added. The active liquid medium is formed in formation under 10-20 MPa pressure and held in the formation for 12-24 hours. Passive liquid medium is removed from well productive zone by performing two-stage impulse-wave depression action. Then hydroimpulsive treatment of bottom zone intervals is performed with the use of pressure booster with flat jet head, which generates flat fan-like jets of technological liquid, wherein impulse frequency is 50-300 impulse per minute, pressure is 1.5-2.5 static pressures in well at formation level. Then passive liquid medium is finally removed from formation zone. The technological liquid is all-purpose surfactant solutions. Device comprises flow string, jet means installed in flow string and provided with active nozzle, mixing chamber, diffuser, active and passive liquid media inlet and outlet channels, as well as packer and pressure booster arranged under jet means. The pressure booster is located under well zone perforation area so that pressure booster may be lifted in several stages. The jet means may operate in two modes. Pressure booster has flat jet head located in lower part thereof. Device additionally has depression impulse generator and impulse-wave depressor arranged in predetermined locations.

EFFECT: increased oil and gas well recovery, improved injection well intake capacity, increased initial well bottom zone permeability.

3 cl, 6 dwg

Description

The invention relates to the oil and gas industry and can be used to clean the bottom-hole zone of a formation — a bottomhole formation zone from clogging materials during development, resuscitation and increasing productivity of wells, including those operated in complicated geological and physical conditions.

There is a known method of processing PZP, carried out by periodically increasing and decreasing the pressure in the well with simultaneous wave action when creating depression on the reservoir, and increasing the pressure on the bottom of the well is carried out at a moderate pace by pumping the liquid medium of the reagent into the reservoir through the annulus or through tubing - tubing with a closed annulus, i.e. create repression. After the repression, a rapid decrease in pressure at the bottom of the bottom is performed, while the generator of elastic vibrations is turned on and the vibrating microwave effect is carried out in conditions of depression. It is assumed that when creating a complete depression in the bottomhole formation zone, along with the removal of suspended particles from the nearest areas, deeper ones are also cleaned up due to the "inclusion" of reservoir pressure and fluid flow already from the reservoir (RF Patent No. 1639127, 1996). This method provides for a periodic impact on the formation, while to improve the reservoir properties of the PPP, a phased effect with the use of specific chemicals and physical methods of stimulating their action at each stage is necessary.

There is also a known method of processing PZ wells, including the injection of a hydrocarbon fluid — a mixture of light pyrolysis resin or products based on it and α-olefins in a ratio of 9: 1-1: 9, forcing it into the formation with a buffer fluid, holding, removal of dissolution products, subsequent injection alkaline solution of the specified concentration, keeping and removal of reaction products, and the injection of hydrocarbon liquid, alkaline solution and removal of dissolution and reaction products is carried out in a repressive-depression wave mode with often toy 1-400 Hz (RF patent No. 2162517, 2001).

The closest analogue to the claimed method is a method of reagent-pulse impact on the well and the reservoir, in which, using a liquid-pulse device, the borehole under-packer zone is treated with active liquid medium and the part is withdrawn to the surface through the packer, then the packer is brought into working position and replaced in the jet apparatus blocking insert on the depressive one, isolating from each other the channels for supplying active and passive liquid media to the jet apparatus with pumping the passive medium through the subject of peripheral check valves installed on the tubing-tubing string below the packer, the active fluid is supplied through the tubing to the nozzle of the jet apparatus and the jet apparatus is pumped out of the reservoir zone of the passive medium, the pressure multiplier installed below the borehole perforation being used as a water pulse device, which begin processing by setting it below the perforation of the near-wellbore zone, and then stepwise or smoothly lift along the well and process with the frequency of pulses from 40 to 70 per minute and with a pressure from 1.5 to 1.7 of the static pressure in the well at the reservoir level, providing a pulsating effect of the active fluid, and non-aggressive fluids are used as the active fluid - for example, oil, unsaturated kerosene, aqueous solutions of acids, saline solutions (RF patent No. 2138696, 1999).

A known installation for hydroimpulse effects on a well, including a shock pulse generator with a striker and a peak emitter, equipped with an end emitter elastically connected to the body of the shock pulse generator, a pump with a pressure accumulator and a water tank, and a distribution chamber mounted vertically and communicated with an inlet a pump and a pressure accumulator and an outlet with a connecting pipe communicated at the wellhead with a tubing blocked by a valve from above, and the peak and the end emitters are mounted coaxially with a sliding fit in the distribution chamber, respectively, above and below it, with the possibility of overlapping its inlet when they move in the opposite direction and are made from the side of the outlet of the distribution chamber with bevels at angles. Both emitters act on the medium synchronously and create one oscillation frequency (RF Patent No. 2130110, 1999). The disadvantage is that a significant part of the energy of the pulses will be lost in the process of transferring it from the surface to the zone of the reservoir.

The closest analogue for the claimed installation is the installation for reagent-pulse impact on the well and the reservoir, containing the CST, installed on it a jet pump with an active nozzle, a mixing chamber, a diffuser, channels for supplying active and passive liquid media, equipped with a packer, a central check valve , by a hydroimpulse device in the form of a pressure multiplier pre-installed on the CST below the packer and below the perforation of the borehole zone, with the possibility of stepwise processing or a smooth rise along the borehole at a frequency of generated pulses of 40-70 per minute and a pressure value of 1.5-1.7 the static pressure in the borehole at the reservoir level, a system of non-return peripheral valves, a blocking insert in which a non-return valve is installed, installed replacing it depending on the operation performed on the depressive insert, while these channels are blocked when the depressive insert is installed by the walls of the latter, and when the depressive insert is installed, these channels are open but isolated from each other by overlapping the cross section of the CSTP with the wall of the depressive insert (RF Patent No. 2138696 1998).

The disadvantage of these methods and installations is the entrainment of particles of colmatizing materials deeper into the formation during processing of the bottomhole formation zone, and their insufficient efficiency.

The aim of the invention is to increase the productivity of oil and gas wells put into operation, increase the injectivity of injection wells, restore and increase the coefficient of productivity and initial permeability of the bottomhole formation zone by reducing the removal of particles of contaminant material deep into the reservoir, control of treatment regimes, phased application of chemical reagents to ensure optimal performance magnetic, depressive and vibrating microwave effects.

This goal is achieved by the fact that in the method of reagent-pulsed impact on the well and the reservoir, including the supply through the pressure multiplier of the active liquid medium to the under-packer zone of the well and further into the reservoir system, followed by a pulsed effect on the liquid medium, the flow of the active liquid medium into the nozzle a jet apparatus and pumping out a passive liquid medium from the reservoir zone of the jet apparatus using a mixture of aliphatic and aromatic hydrocarbon solvents with ext by pre-treatment of a demulsifier solution in one of the indicated solvents pretreated in a constant magnetic field, the mixture is crushed into the formation at a pressure of 10-20 MPa, exposure is carried out for 12-24 hours, the passive liquid medium is removed from the bottom-hole zone of the formation by wave unloading of the well by pulse-wave depressive effect in two modes - reverse water hammer and a sharp opening pre-loaded with pressure wells, then using a pressure multiplier with a flat-bladed head carry out gy a pulsed interval treatment of the borehole zone with technological fluid with flat fan streams with a pulse frequency of 50-300 per min and a pressure value of 1.5-2.5 the static pressure in the well at the reservoir level, after which the passive liquid medium is finally removed from the reservoir zone. Moreover, it is preferable to use an aqueous solution of multifunctional surfactant compositions as a process fluid.

This goal is also achieved by the fact that in the installation for reagent-pulse impact on the well and the reservoir containing a string of tubing CT, installed on it a jet pump with an active nozzle, a mixing chamber, a diffuser, channels for supplying active and passive liquid media, under the jet pump there is a sequentially packer, a water-pulse device in the form of a pressure multiplier, located below the perforation of the borehole zone, with the possibility of processing a stepped rise of the specified multip liquefaction along the well, the jet pump is made dual-mode, having a check valve installed in a movable sleeve, equipped with a locking ring and coaxially mounted in the housing of the jet pump, in which there is an annular groove for fixing the movable sleeve when the locking ring enters the zone of the annular groove in the housing, and To compensate for the movement of the movable sleeve, a buffer valve is installed in the housing, blocking the flow of active liquid medium to the pressure multiplier and translating its flow through the spline channels into the movable To the second sleeve into the channel and further into the active nozzle of the jet pump with its inclusion in operation, the pressure multiplier is equipped with a flat-jet head in its lower part, with the possibility of generating flat fan jets with a frequency of pulses of 50-300 per minute and with a pressure of 1.5- 2.5 values of static pressure in the well at the reservoir level, and the installation is additionally equipped with a depressive pulse generator located below the pressure multiplier and installed on the surface of the earth with a pulse-wave depressor rum, consisting of a discharge chamber connected to the annular space, in which a spring-loaded sleeve and a plunger are mounted with the possibility of displacement and lock mating, driven by a hydraulic cylinder with a spring-loaded piston with the possibility of hydraulic closure of the piston cavity with a hydraulic lock controlled by a control valve supplied from a hydraulic pump connected to Baku, and the discharge chamber has a drainage free hydraulic outlet into the drain tank.

Figure 1 shows the reagent-pulse well installation during the hydro-pulse treatment of the well using a pressure multiplier and the supply of active liquid medium to the bottom-hole zone of the well;

figure 2 - during the landing of the packer and the subsequent crushing of the active liquid medium into the reservoir with a certain rest time for the implementation of chemical reactions;

figure 3 - during the period of repression;

figure 4 - during the depression of the unloading of the well after the packer is broken and the wave treatment of the bottom-hole zone by a depression pulse device installed on the surface of the earth, and with the removal of separated clogging particles to the surface and their discharge into a separate container or collector;

figure 5 - during the interval of processing the thickness of the reservoir with periodic pressure pulses using a pressure multiplier;

figure 6 - during the switching of the jet pump to the working position with subsequent pumping of the medium from the well and its final cleaning.

Installation for implementing the method of reagent-pulse impact on the well and the reservoir - reagent-pulse well installation contains:

Mounted on a tubing string - KNKT (1) a dual-mode jet apparatus (jet pump) with an active nozzle (2), a mixing chamber (3), a diffuser (4), a channel (5) for supplying active liquid medium from the one installed on the ground a hydraulic pump (6) and a channel (7) for supplying a passive liquid medium from the bottomhole zone. To implement two operating modes, the inkjet apparatus has a check valve (8) mounted in a movable sleeve (9), which is equipped with a lock ring (10). The sleeve (9) is coaxially mounted in the housing (11) of the inkjet apparatus. In the housing (11) there is an annular groove (12) for fixing the sleeve (9) when the retaining ring (10) enters the zone of the annular groove (12). To compensate for the stroke of the sleeve (9), a buffer valve (13) is installed in the housing, which blocks the fluid flow to the multiplier and transfers its supply through the splined channels (14) in the sleeve (9) to the channel (15) and then to the jet nozzle (2) apparatus with its inclusion in the work. Under the jet apparatus, a packer (16), as well as a pressure multiplier (17) and a depressive pulse generator (18) are located in series, which are located before the implementation of the method slightly lower than the perforation of the borehole formation zone.

A pulsed-wave depressor is installed on the surface of the earth, consisting of a discharge chamber (19) connected to the annular space, in which a plunger (20) and a spring-loaded sleeve (21) are mounted with the possibility of displacement and locking. The plunger (20) is driven by a hydraulic cylinder (22) with a spring-loaded piston (23) and with the possibility of hydraulic closure of the piston cavity by a hydraulic lock (24) controlled by a control valve (25) with a feed from a hydraulic pump (26) connected to the tank (27). The discharge chamber (20) has a drainage free hydraulic outlet into the drain tank (28).

The claimed method of reagent-pulse impact on the well and the reservoir using the claimed installation is implemented as follows.

At the initial stage of the treatment cycle, through a CSTP lowered to the bottom with a jet apparatus, a packer, a pressure multiplier using a hydraulic pump (6) (Fig. 1), an active liquid medium is supplied - a mixture of aliphatic and aromatic solvents, for example, a straight-run fraction of gasoline containing 70-80% paraffins and toluene the rest, with the addition of 0.01-0.1% of the marketable form of a demulsifier, such as Penta 483, Disolvan, previously dissolved in one of the solvents used, for example toluene at a 50% concentration, the specified 50% solution P it is re-processed in a constant magnetic field with an intensity of 80-115 kA / m at a flow rate of a solution flow through a flow-type magnetizing device of 0.5-1.5 m / s, which provides an increase in the depth and rate of destruction of stable oil-water emulsions and a decrease in interfacial tension by structuring the demulsifier solution and increasing its surface activity. In this case, the sleeve (9) of the inkjet apparatus occupies the lowest position, blocking the entrance to the working channel (15) of the inkjet apparatus with a conical flange and at the same time passing the liquid medium (this mixture) through the open check valve (8) down to the multiplier (17). When lowering the liquid medium into the region of the bottom-hole zone, a packer (16) is installed and the annulus is closed (Fig. 2). After that, at a moderate pace, pressure is increased at the bottom of the well by injection into the bottomhole zone of the formation of the bottomhole formation zone. The process of injecting a solvent mixture with the addition of the specified solution of the demulsifier is carried out at a pressure level limited by the hydraulic fracturing pressure, while the number of reagents is calculated based on the productive capacity of the formation and its reservoir properties, but not less than 0.7 m ^{3 of the} specified solvent mixture per 1 m of thickness . The mixture is pushed into the reservoir with a process fluid - light oil, NGL (a wide fraction of light hydrocarbons), gas condensate or an aqueous solution of a surfactant complex to provide a pressure of 10-20 MPa, the well is stopped to dissolve the paraffin deposits (asphalt-resinous-paraffin deposits) and the destruction of water-oil emulsions in within 12-24 hours. An aqueous solution of a complex of surfactants (surfactants), i.e. multifunctional surfactant compositions such as ML-51, ML-80, VRK, VRK-SS, NMK (L.M. Gurvich and N.M.Sherstnev. Multifunctional surfactant compositions in oil production processes, Moscow, VNIIOENG, 1994, p. 158-160).

Since this does not produce a vibrating microwave effect, pollution and clogging particles are not carried deeper into the formation. Next, the packer is torn off and the cyclical removal of dissolved paraffin deposits and particles of clogging material is carried out by the operation of the pulse-wave depressor of the internal combustion engine installed on the surface of the earth. Each cycle of the IED operation consists of a well load by pressure when the conical surface of the plunger (20) and the sleeve (21) are closed. A liquid contaminated with colmatants (a passive liquid medium) is discharged into a tank (28) or a by-pass collector. The closing and opening of the plunger (20) and the sleeve (21) are controlled by means of a hydraulic lock (24) and a distributor (25).

The process of removing contaminants is completed when the previously pumped volume of the indicated mixture of solvents is removed from the PZP, since with further repression to the formation, formation fluid can exit and degass with paraffin.

After the passive liquid medium with contaminating materials is brought to the surface, the bottom-hole zone is periodically treated with a process fluid - light oil, BFLH, straight-run gasoline, an aqueous solution of a surfactant complex using a pressure multiplier (17) (Fig. 5). In this case, pressure fluctuations are maintained at a level of 10-15 MPa with a frequency of 3-5 oscillations per minute.

After treatment with a pressure multiplier, first disconnect the hydraulic pump supply (6) through the tubing and connect it to the annulus. By increasing the pressure in the annulus, the check valve (8) of the jet apparatus blocks the flow from below into the tubing and, under the influence of pressure, the sleeve (9) rises up to the position where the retaining ring (10) fits into the annular groove (12). Up to this point, the end part of the sleeve is blocked by a buffer valve (13). Thus, the working fluid has access to the nozzle of the jet apparatus from the side of the hydraulic pump (6) and the injection fluid from the lower part has access to the mixing chamber (3), carrying out the removal of polluting particles to the surface.

Next, the packer is installed a second time and the feed from the hydraulic pump (6) is again connected to the tubing (Fig.6). When the jet apparatus operates in the tubing below the packer, a depression of a certain value is created at which the DGI depression pulse generator is turned on (18), which consists of a system of check valves that operate when the pressure difference in the annulus and tubing is reached. Using DGI, a repeatable implosion effect is created in the well’s PZ.

With repeated implosion exposure, the most favorable conditions are created for the destruction of paraffin deposits, the separation of the clogging particles from the surface of the perforation channels, their dispersion in the fluid and their removal from the most contaminated area of the formation directly adjacent to the well. As the bottom-hole zone is cleared deeper, the magnitude of the depression will gradually decrease, but the radius of the depression treatment will also increase.

Given the fact that the adhesion strength of colmatants to the collector decreases as well as the number of paraffin deposits with increasing distance from the well, the high efficiency of removing contaminants throughout the depth of the bottomhole zone is maintained.

Thus, the injection of the indicated mixture of hydrocarbon solvents with the addition of the specified demulsifier solution into the bottomhole zone of the well, the holding of this mixture, pumped into the reservoir under pressure to dissolve the ARPD, the destruction of water-oil emulsions and the reduction of the surface tension of water in the capillary channels, the wave unloading of the well with the implementation of the reverse water hammer mode and instant opening of the well, pre-loaded with pressure, removal of the dissolution products of paraffin and other clogging contaminants of the jet with an apparatus with simultaneous implementation of the implosion effect due to adjustable check valves installed on the tubing string below the packer, hydraulic pulse treatment of the borehole zone using a pressure multiplier with the generation of flat fan streams of liquid, for example, an aqueous solution of multifunctional surfactant compositions with a pulse frequency of 50 -300 per minute and with a pressure value of 1.5-2.5 the static pressure in the well at the reservoir level, the final removal of clogging contaminants fusion from the bottomhole zone of the formation with a jet apparatus with simultaneous implementation of the implosion effect due to adjustable check valves installed on the tubing string below the packer, i.e. The method of reagent-pulse impact on the well and the reservoir, carried out using the claimed installation, provides an increase in the efficiency of cleaning the bottom-hole zone of the BHP formation and, accordingly, an increase in the productivity of wells put into operation, injectivity of injection wells, restoration and increase in the productivity coefficient and initial permeability of the BHP.

Claims (3)

1. The method of reagent-pulse impact on the well and the reservoir, including the supply through the pressure multiplier of the active liquid medium to the under-packer zone of the well and further into the reservoir system, followed by the pulsed effect on the liquid medium, the supply of the active liquid medium to the nozzle of the jet apparatus and pumping by the jet apparatus from the reservoir zone of a passive liquid medium, characterized in that a mixture of aliphatic and aromatic hydrocarbon solvents with an additive is used as an active liquid medium of a demulsifier solution treated in a constant magnetic field in one of these solvents, the mixture is crushed into the reservoir at a pressure of 10-20 MPa, aging is carried out for 12-24 hours, passive liquid medium is removed from the bottom-hole formation zone by wave unloading of the well by pulse-wave depression action in two modes - reverse water hammer and a sharp opening pre-loaded with pressure wells, then using a pressure multiplier with a flat-blast head carry out a hydro-pulse interval processing of the borehole zone with technological fluid with flat fan jets with a pulse frequency of 50-300 per minute and a pressure value of 1.5-2.5 of the static pressure in the well at the reservoir level, after which the passive liquid medium is finally removed from the reservoir zone 2. The method according to claim 1, characterized in that an aqueous solution of multifunctional surfactant compositions is used as a process fluid. 3. Installation for reagent-pulse impact on the well and the reservoir containing a tubing string, an inkjet apparatus installed on it with an active nozzle, a mixing chamber, a diffuser, active and passive liquid medium supply channels, a packer sequentially placed under the jet apparatus, a water-pulse device in the form of a pressure multiplier located below the perforation of the borehole zone with the possibility of processing the stepwise rise of the specified multiplier along the well, characterized in that the jet apparatus is made dual-mode, having a check valve installed in a movable sleeve provided with a retaining ring and coaxially mounted in the housing of the jet apparatus, in which there is an annular groove for fixing the movable sleeve when the retaining ring enters the zone of the annular groove in the housing, and To compensate for the movement of the movable sleeve, a buffer valve is installed in the housing, blocking the flow of the active liquid medium to the pressure multiplier and translating its flow through the spline channels into the movable w in the channel and further into the active nozzle of the jet apparatus with its inclusion in operation, the pressure multiplier is equipped with a flat-jet head in its lower part, with the possibility of generating flat fan jets with a pulse frequency of 50-300 per minute and with a pressure of 1.5-2 , 5 values of static pressure in the well at the reservoir level, and the installation is additionally equipped with a depression pulse generator located under the pressure multiplier and a pulse-wave depressor mounted on the surface of the earth consisting of a discharge chamber connected to the annular space, in which a spring-loaded sleeve and a plunger are mounted with the possibility of moving and locking mating, driven by a hydraulic cylinder with a spring-loaded piston with the possibility of hydraulic locking of the piston cavity with a hydraulic lock controlled by a control valve supplied from a hydraulic pump connected to the tank and the discharge chamber has a drainage free hydraulic outlet into the drain tank.

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