RU2327862C1 - Method for affecting bottomhole well zone - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to the oil industry and can be used in affecting the bottomhole well zone for productivity improvement. The method includes impacting the bottomhole with the falling weight with simultaneous injecting liquid into the well and lifting the plunger by hydraulic energy of the liquid flow injected into the well; after the each weight knock, the additional knock at the bottomhole is made by falling plunger via load; the bottomhole zone is treated by hydraulic pressure pulsations simultaneously with knocking, and the chemical reagents are injected into the bottomhole zone. The invention is developed in dependent points.

EFFECT: efficiency of affecting well bottomhole zone is increased.

5 cl, 3 dwg

Description

The invention relates to the oil industry and can be used when acting on the bottom-hole zone to increase well productivity.

A known method of vibro-seismic impact on a reservoir, including applying impacts with a falling load to the bottom at the same time as oil production from the exciting well and lifting the load using the piston by using the energy of the medium flow extracted from the well, and after each strike at the bottom of the load, they strike an additional bottom strike a falling piston (RF patent No. 2206729, CL ЕВВ 43/25, 28/00, 2003). The known method has a limited scope.

Closest to the claimed invention is a method of vibro-seismic impact on a reservoir, comprising applying impacts with a falling load to the bottom simultaneously with pumping fluid into the well and lifting the cargo using a plunger by using hydraulic energy of the fluid flow pumped into the well, and after each impact, the load is applied impact on the face by a falling plunger through the load (RF patent No. 2258127, CL ЕВВ 28/00, 43/16, 2005). In the known technical solution, the effect is carried out only by striking the face, which limits the effectiveness of the method.

The objective of the invention is to increase the efficiency of the method by jointly affecting the bottom-hole zone not only by impacts on the bottom, but also by hydraulic pressure pulsations, as well as by solutions of chemical reagents.

Improving the efficiency in the method of influencing the bottom-hole zone of the well is achieved by the fact that in the method of influencing the bottom-hole zone of the well, including applying impacts with a falling load along the bottom simultaneously with pumping the liquid into the well and lifting the load using the plunger due to the use of hydraulic energy of the liquid flow pumped into a well, and after each impact with a load, an additional blow is applied to the face by a falling plunger through the load, according to the invention, together with striking with a load and a piston along the bottom of the well, the bottom-hole zone is treated with hydraulic pressure pulsations and chemical reagents are pumped into the bottom-hole zone.

In another embodiment of the method, after the solution of chemical reagents is injected into the bottomhole zone of the well, the fluid is circulated in the well while striking the bottom of the well with a load and a piston and applying pressure pulsations to the bottomhole zone for the entire reaction period in the bottomhole zone.

In variants of the method, after completion of the response in the bottom-hole zone, the well is developed by replacing the fluid circulating in the well with a medium of lower density, while striking with the load and the piston along the bottom of the well and applying pressure pulsations to the bottom-hole zone for the entire development period, and also drill a well with aerated fluid or foam.

The specified set of distinctive features of the claimed invention makes it possible to conduct effective treatment of the bottomhole zone of the well with joint impact on the formation by impacts with the load along the bottom, hydraulic pressure pulsations and solutions of chemical reagents.

Figure 1 shows the installation diagram for impacting the bottom-hole zone of a well with an open annular space, figure 2 - installation diagram for impacting the bottom-hole zone of a well with an closed annular space, figure 3 - downhole well assembly.

The installation for impacting the bottom-hole zone 1 of the well 2, drilled into the formation 3, comprises a downhole aggregate 5 lowered on the tubing string 4, consisting of a seismic wave generator 6 and a spring-valve pulsator 7, a packer 8 and a telescopic compensator 9 of the installation displacements when striking. Depending on the ongoing technological operation, the packer 8 can be either in the transport position (see figure 1), or in the unpacked state (see figure 2). Downhole downhole unit 5 is mounted with support on a cement bridge 10 at the bottom of a well 2.

The seismic wave generator 6 contains a load 11 for striking, located in the wellbore 2, a lifting device 12, connected with the load 11, and the anvil 13. The lifting device 12 is made in the form of a housing 14, in which there is a through plunger 15, a valve 16 and an upper limiter 17 lifting the plunger 15. The valve 16 is connected directly to the load 11 and is the lower limiter for the fall of the plunger 15. The lower part of the through plunger 15 is equipped with a seat 18. The load 11 with the valve 16 are used to transmit the energy of impacts of the falling plunger 15 to the anvil 13. Anvil 13, standing on the cement bridge 10.

The housing 14 of the lifting device 12 and the load 11 are placed inside the outer pipe 19, the upper end of which is connected to the column of tubing 4 by means of channels 20, and the lower end is connected to the anvil 13.

The output line 21 of the lifting device 12 is equipped with a spring-valve pulsator 7, the output channels 22 of which are in communication with the space of the well 2. The spring-valve pulsator 7 contains a valve 23 with a stem 24, a seat 25, a spring 26, a screw 27, a lock nut 28 and a cover 29 The pressing of the valve 23 to the seat 25 is provided by a spring 26, the tension of which is regulated by a screw 27. The lock nut 28 is designed to fix the screw 27, and the cover 29 is used to seal the cavity of the pulsator 7 from the tubing string 4.

Valve 16 is provided with a stem 30.

The method of impact on the bottomhole zone of the well is as follows.

Slaughter strikes are carried out using a seismic wave generator 6.

The process fluid is pumped through the tubing string 4 and through the channels 20 into the internal cavity of the downhole borehole unit 5. Further, through the annular space between the outer pipe 19 and the housing 14, the fluid is fed into the internal cavity of the housing 14.

A prerequisite for the normal functioning of the downhole unit 5 is to ensure contact between it and the bottom of the well 2, i.e. the anvil 13 should rest on a cement bridge 10. During operation, the occurrence of a gap between the downhole borehole unit 5 and the cement bridge 10 is eliminated by a telescopic compensator 9, which allows the downhole borehole unit 5 to move down when the packer 8 is stationary.

At the beginning of the upstroke phase, the through plunger 15 and the load 11 are located in the lower position. In this case, the load 11 rests on the anvil 13, and the plunger 15 presses the seat 18 against the valve 16 under the action of gravity. The process fluid under pressure acts from below on the load 11, valve 16 and the end surface of the through plunger 15. All of these parts move upward as a single whole. During the stroke of the downhole tool 11 upward, its ascent rate is determined by the flow rate of the process fluid supplied from the surface by the pumping unit through the tubing string 4. The fluid located above the through plunger 15 is forced up into the output line 21 of the lifting device 12 and is spring-loaded valve pulsator 7.

The lifting process continues until the rod 30 abuts against the upper stop 17. In this case, the through plunger 15 continues to rise upward by inertia. As a result, a gap is formed between the seat 18 of the plunger 15 and the valve 16. The fluid pressure forces acting on the load 11 above and below are aligned, the load 11 with the valve 16 and the stem 30 stops, and then begins to fall down. Following him, through the plunger 15 moves with lower speed. When falling, in the lower position, the load 11 hits the anvil 13 at the bottom of the well 2. In this case, the kinetic energy of the load 11 is converted to the energy of seismic waves.

After the load 11 falls on it, the through plunger 15 is lowered, making an additional blow to the face through the load 11 with the valve 16 and the anvil 13, additionally generating seismic waves in the reservoir 3. After the through plunger 15 drops on the load 11, the valve 16 will close the passage in the saddle 18 and the pressure of the process fluid will ensure the upward stroke.

During the course of the load 11, the process fluid flows, flowing through it, through the passage in the saddle 18 along the internal channel of the through plunger 15 and enters the input of the spring-valve pulsator 7.

Thus, there is an alternation of the phases of the lifting of the load 11 and its fall. The seismic waves that occur during impacts, which propagate from the anvil 13 through the cement bridge 10 and the production casing of the well 2 along the skeleton of the formation 3 into the bottomhole zone 1, intensify the process of its decolmation. This leads to an increase in permeability and increase the productivity of the well 2.

Hydraulic pressure pulsations are created by means of a spring-valve pulsator 7. It works due to the energy of the fluid flow entering it after the passage of the seismic wave generator 6. The pressure of the process fluid acts on the lower end of the valve 23 and increases until it rises, overcoming spring tension 26, and will skip a portion of the process fluid. After that, the pressure of the liquid under the end of the valve 23 decreases, the valve 23 closes and the process of increasing pressure is repeated.

The fluid passing through the valve 23, through the output channels 22 enters the cavity of the well 2. The vibration of the valve 23 leads to the appearance of hydraulic pressure pulsations, which propagate into the pores and fractures of the formation 3 filled with liquid, contributing to a more intensive cleaning of the bottom-hole zone 1 from contamination.

It should be emphasized that the simultaneous action of seismic waves on the formation skeleton and hydraulic pressure pulses on the voids of the reservoir rock filled with liquid gives a synergistic effect.

Actually, vibroseismic action leads to partial destruction of the colmatant due to the effect of long-wavelength resonance, which consists in the transfer of energy passing in the medium of the seismic wave to the energy of ultrasonic waves arising from the scattering of the seismic wave by the inhomogeneities of the porous collector. Fragments of colmatant formed after destruction are carried out further from the feather space of the collector by natural filtration flow. As a result, the permeability of the reservoir increases.

Hydropulse action is also aimed at increasing permeability, firstly, by destroying the clogging substance due to the passage of a pressure wave in the fluid saturating the reservoir, and secondly, by intensifying the process of removal of fracture products by hydraulic pulses passing through the medium.

The joint implementation of both processes leads to an increase in the effectiveness of each of them: the increase in permeability due to impacts by striking the face and generating seismic waves increases due to the intensification of the removal of destroyed collimant by hydraulic pulses, and the efficiency of hydro-pulse fracture of collimant increases due to a decrease in the tensile strength of the substance of collimant in the ultrasonic field radiation arising from the scattering of seismic waves generated in the process applied I'm hitting the slaughter.

Due to these reasons, the total effect with simultaneous vibroseismic and hydroimpulse effects will be higher than the simple sum of the results of their application, since the effectiveness of each of them increases.

Correspondingly, the addition of chemical reagents during joint strikes on the formation and hydroimpulse treatment leads to a sharp intensification of the dissolution and dispersion of the cobaltant during the reaction in the near-wellbore zone, which gives an additional super-total increase in permeability recovery.

The transportation of the solution of chemical reagents to the bottom of the well 2 is carried out in the fluid circulation mode. In this case, the packer 8 is in the transport position and the annulus is open. The fluid passes through a seismic wave generator 6, a spring-valve pulsator 7, which contributes to both the excitation of seismic waves and hydraulic pulsations.

After a portion of the chemical reagent solution reaches the bottom, block the annular space of the well 2 above the formation 3 by means of a packer 8 and pump the chemical reagent into the bottom-hole zone 1 of the well 2 with simultaneous exposure to seismic waves and hydraulic pulses using the downhole aggregate 5.

After pumping a solution of chemical reagents into the bottomhole zone 1 of the well 2, the packer 8 is brought into the transport position, i.e. open the annular space of the borehole 2 above the formation 3 and circulate the fluid pumped into the borehole during the entire reaction period in the bottomhole zone when the borehole bottomhole unit is exposed to 5 impacts and hydraulic pulses.

At the end of the response, in the bottom-hole zone 1, the development of well 2 is carried out by replacing the fluid circulating in the well 2 with a medium of lower density (for example, oil, aerated fluid, foam, etc.). The fluid is replaced by direct circulation through the tubing string 4 and the downhole unit 5, therefore, striking the face and the impact of hydraulic pressure pulses during well development does not stop, which contributes to the best process efficiency.

Thus, total impact on the bottom-hole zone by seismic waves, hydraulic pressure pulsations and solutions of chemical reagents is carried out. The impact of seismic waves and hydraulic pulsations is carried out not only during the entire period of treatment of the bottom-hole zone and response, but also in the process of subsequent development of the well. This makes it possible to achieve a significantly larger increase in well productivity than using any of these types of impact individually.

Therefore, the proposed technical solution can significantly increase the effectiveness of the impact on the bottomhole zone in comparison with the known inventions.

Claims (5)

1. A method of influencing the bottom-hole zone of a well, including applying impacts with a falling load to the bottom along with pumping liquid into the well and lifting the load with the help of a plunger by using hydraulic energy of the fluid flow pumped into the well, and after each hit with the load, an additional blow is made to the bottom a falling plunger through the load, characterized in that, together with striking with the load and the piston along the bottom of the well, the bottom-hole zone is treated with hydraulic pressure pulsations and injection chemicals into the bottom zone. 2. The method according to claim 1, characterized in that after the injection of a solution of chemical reagents into the bottomhole zone of the well, the fluid is circulated in the well while striking with the load and the piston along the bottom of the well and exposing the bottomhole to hydraulic pressure pulsations during the entire reaction period in bottomhole zone. 3. The method according to claim 2, characterized in that after completion of the reaction in the bottomhole zone, the well is developed by replacing the fluid circulating in the well with a medium of lower density, while simultaneously striking the bottom of the well with a load and a piston and applying hydraulic pressure pulsations throughout the development period. 4. The method according to claim 3, characterized in that the well is mastered with aerated fluid. 5. The method according to claim 3, characterized in that the well is mastered with foam.

Images