RU2515623C1 - Installation for vibroseismic impact on deposit - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: installation contains a hammer for making impacts, a borehole lift appliance connected to the hammer and an anvil. The lift appliance is made as a body containing a plunger with a feedthrough, a centraliser-lift limiter for the hammer made as a sleeve bearing with a feedthrough holes and a valve with a saddle. The valve is connected to the rod which is connected to the hammer by means of a liquid damper. The space between the outer surface of the lift appliance body and the inner surface of the well is covered by the packer while the space above the plunger of the lift appliance has a hydraulic link with a suction line of a borehole pump.

EFFECT: invention allows increasing reliability and operability of the installation.

4 cl, 7 dwg

Description

The invention relates to the oil industry and can be used with vibroseismic exposure to increase oil recovery.

A known installation for striking with a falling striker against a reservoir exposed by an exciting well using hydraulic energy to lift a striker, comprising a striker for striking, a hoisting device located in the wellbore associated with the striker, a striker lifter breaker and an anvil (RU 2106471, 1998).

The known installation has low functionality and limited scope due to the need to stop oil production from an exciting well for the entire period of exposure.

There is also known a device for vibro-seismic impact on a reservoir containing a striker for striking, located in the wellbore a lifting device associated with the striker, and the anvil, and the lifting device is made in the form of a housing in which there is a plunger with a passage channel, a valve and an upper lift limiter the plunger, while the space between the outer surface of the housing of the lifting device and the inner surface of the well is blocked by the packer, and the space above the plunger of the lifting device It is in fluid communication with suction line downhole pump (RU 2164287, 2001). The operation of this installation consists in striking a falling hammer on the formation simultaneously with oil production from an exciting well and raising the hammer with a plunger due to the use of the energy of the medium flow extracted from the well.

The known device, as shown by experimental bench tests, have low reliability and limited functionality. This is a consequence of the connection of the valve and the hammer using a flexible rope, which was repeatedly torn during the bench tests. In addition, due to the flexible connection between the valve and the hammer, the plunger, when falling down, made useless hits on the lower limiter installed in the housing of the lifting device. Tests also showed that at high fluid flows, the valve detaches from the plunger at the very beginning of the up stroke due to the abrupt transfer of the weight of the hammer to the valve. The installation completely lost its operability.

Closest to the claimed invention is an installation containing a striker for striking, located in the wellbore a lifting device associated with the striker, and the anvil, and the lifting device is made in the form of a housing in which there is a plunger with a passage channel, a centralizer-limiter for raising the striker and valve, while the space between the outer surface of the housing of the lifting device and the inner surface of the well is blocked by the packer, and the space above the plunger of the lifting device has in fluid communication with the suction line of the downhole pump, the valve is connected to the hammer through a rod and a lower limiter plunger fall and the hammer with the rod and valve stem are used to transmit the energy incident on the plunger strikes the anvil (RU 2206729, 2003). In embodiments of the installation, the connection of the lower part of the rod with the hammer is movable, the lower part of the rod having a fifth, and in the upper part of the hammer there is a cavity with a cover in which there is a hole for the passage of the rod, and a compression spring is installed between the fifth rod and the cover.

The known device, as shown by field tests, has low reliability.

In an embodiment of the known installation, the taper angle of the valve is in the range from 1 to 10 °. This condition was to provide an effective conical grip and to increase the reliability of adhesion between the valve and the plunger by lifting the hammer. However, experiments have shown that this taper angle provides such a strong conical grip that subsequent separation of the valve and the plunger requires enormous values of the working fluid pressure on the end surface of the plunger, which is a sharply negative factor in downhole conditions.

In another embodiment of the known installation, levers are mounted on the valve to create additional force for opening the valve, while the plunger is provided with an emphasis for levers. This should have made it possible to quickly and reliably open the valve at the top of the lift without creating an excessive pressure drop. However, studies have shown that in the presence of mechanical impurities and corrosive substances in well production, the reliability of this mechanism is low.

The objective of the invention is to increase the reliability of the installation for vibro-seismic effects on the reservoir and provide optimal control of the operating mode of the installation, regardless of the flow rate of the well products.

This object is achieved in that the installation for vibro-seismic impact on the reservoir contains a hammer for striking, located in the wellbore lifting device associated with the hammer, and the anvil, and the lifting device is made in the form of a housing in which a plunger with a passage channel, the centralizer the hammer lift limiter, made in the form of a sliding bearing with bores, and a valve with a seat, while the valve is connected to a rod connected to the hammer through a hydraulic the damper, the space between the outer surface of the housing of the lifting device and the inner surface of the well is blocked by the packer, and the space above the plunger of the lifting device has a hydraulic connection with the suction line of the downhole pump,

In preferred embodiments of the installation:

- the plunger is made collapsible,

- the seat is equipped with a magnet to provide additional pressure against the valve,

- the lower part of the rod is provided with a fifth, and in the upper part of the hammer there is a cavity with a cover in which a hole is made for the passage of the rod.

Achievable technical result consists in expanding the functionality of the installation, in improving the adhesion of the plunger and valve, as well as reducing shock loads on the rod.

The expansion of the installation functionality for vibro-seismic impact on the reservoir is achieved by the fact that the plunger is collapsible, consisting of directly the plunger and the seat, which allows you to change the operating mode of the installation by replacing the saddle with one passage section with a saddle with another (smaller or larger), by changing the operating mode of the installation.

Improving the reliability and operability of the installation for vibro-seismic impact on the reservoir is achieved by the fact that the saddle incorporates a samarium-cobalt magnet, which provides the necessary additional force to capture the valve.

An increase in the MTBF is achieved by the fact that the connection between the lower part of the rod and the hammer is a hydraulic damper, so the lower part of the rod is equipped with a fifth, and in the upper part of the hammer there is a cavity with a cover in which there is a hole for the passage of the rod. Holes are made in the cavity of the upper part of the hammer, connecting the cavity with the space of the well. This design, on the one hand, allows you to smoothly transfer the load from the weight of the drummer to the plunger of the lifting device at the beginning of the upward stroke and eliminates the risk of a sharp detachment of the plunger from the valve, and on the other hand, reduces the negative impact on the rod when the plunger falls on the valve. The holes serve to eliminate the piston effect when the rod moves with the fifth relative to the hammer. The absence of a compression spring between the fifth rod and the cover, the elastic forces of which increase the likelihood of uncoupling the valve and seat, with the presence of damped spring oscillations that occur when the plunger falls on the valve and continues during their further joint movement, also increases the reliability of the installation.

Figure 1 shows the installation diagram for vibroseismic impact on the reservoir, figure 2 shows a diagram of a collapsible plunger, figure 3 shows a diagram of the valve and seat, figure 4 - hydraulic damper.

Installation for vibroseismic impact on the reservoir (see figure 1) contains a drummer 1 for striking, located in the wellbore 2 lifting device 3, associated with the hammer 1, and the anvil 4. The lifting device 3 is made in the form of a housing 5, in which a plunger 6 with a passage channel 7, a valve 8 and a centralizer-limiter 9 for raising the hammer 1, while the space between the outer surface of the housing 5 of the lifting device 3 and the inner surface of the well 2 is blocked by the packer 10, and the space 11 above the plunger 6 of the lifting device The property 3 has a hydraulic connection with the suction line 12 of the downhole pump 13. The valve 8 is connected to the hammer 1 by means of the rod 14. The anvil 4 is connected via the element 15 (for example, a cement bridge) to the reservoir 16. A cuff 17 is located on the rod 14, which is necessary to create the elastic stop of the striker 1 in the centralizer-limiter 9 when the striker 1 reaches its upper position.

Figure 2 presents a design diagram of a collapsible plunger, which directly includes a plunger 6 and a seat 18, which allows you to quickly change the seat 18, in order to change the operating mode of the installation and replace the contact surface 19 of the seat 18 worn during operation.

Figure 3 presents the connection diagram of the valve 8 and the seat 18, in the construction of which there is a magnet 21, in order to ensure effective grip when the seat 18 is engaged with the valve 8. The magnet 21 is located in the seat 18 so that the power magnetic lines are closed through the valve 8 , thereby providing additional force pressing the valve 8 to the seat 18. The position of the magnet 21 is fixed using the cover 20.

Figure 4 presents the hydraulic damper, designed as a connection of the lower part of the rod 14 with the hammer 1, which serves to reduce the dynamic shock loads that occur when the plunger 6 falls on the valve 8.

The lower part of the rod 14 is provided with a fifth 23, and in the upper part of the striker 1 there is a cavity 24 with a cover 25 in which a hole 26 is made for passage of the rod 14. In the cavity 24 of the upper part of the striker 1, holes 28 and 29 can be located connecting the cavity 24 with well space 2.

In this case, the centering of the rod 14, which provides the centering of the valve 8 and the hammer 1, is achieved using the centralizer-fall limiter of the hammer 9, which also acts as a limiter for raising the hammer, made in the form of a sliding bearing having passage holes, so that when the hammer reaches the upper the position and stop of the cuff in the centralizer-limiter of the hole remain open, and through them the flow of well products passes unhindered, while ensuring continuity of flow and continuity process operation of the well.

Installation for vibroseismic effects on the reservoir works as follows.

The rise of the hammer 1 is carried out by using the hydraulic energy of the medium extracted from the well 2. The pump 13 pumps out through the suction line 12 the production of the well 2 from the formation 16 to the surface. Since the space between the outer surface of the housing 5 of the lifting device 3 and the inner surface of the well 2 is blocked by the packer 10, a vacuum is created in the space 11 above the plunger 6, which is in fluid communication with the suction line 12 of the downhole pump 13. The valve 8 is pressed by the pressure of the borehole fluid to the plunger 6 and closes the passage channel 7. The plunger 6 with the valve 8 begins to move upward under the influence of the borehole medium and raises the hammer 1 connected to the valve 8 through the rod 14.

When lifting the plunger 6 with the hammer 1 to its highest position, the hammer 1 abuts the cuff 17 against the centralizer-limiter 9 of raising the hammer 1. Through the holes in the centralizer-limiter 9 of raising the hammer 1, the flow of the borehole medium continues, creating pressure on the end ring surface of the piston 6 ( in particular, seats 18), thereby seeking to open the connection of valve 8 and plunger 6 (in particular, seats 18). The valve 8 opens and the impactor 1 falls onto the anvil 4. The plunger 6 falls down after the arrangement, including the impactor 1, the stem 14 and valve 8. The well fluid flows freely through the passage 7 upward. After striking the anvil 4 and the reservoir 16 with the hammer 1, the plunger 6 falls on the valve 8. The passage channel 7 is thus blocked. Then, under the pressure of the borehole fluid, the plunger 6 and the valve 8 move upward, raising the hammer 1 by the rod 14 to its highest position, etc.

Such repeated cycles of lifting, falling and striking by the striker 1 allow you to maintain intense vibrations in the reservoir 15. Vibrational processes in the reservoir help to reduce the water cut of the produced oil and increase the final oil recovery. In this case, oil production from well 2 during the impact on the reservoir does not stop.

In the case of the execution of the plunger 6 (see figure 2) collapsible, it becomes possible to quickly replace the seat 18, in order to change the operating mode of the installation and replace the contact surface 19 of the seat 18 worn during operation, without the need to replace the entire plunger 6. Moreover, when changing a saddle with one bore to a saddle with another (smaller or larger) bore, a change in the operating mode of the installation occurs, regardless of the mode of operation of the well.

In the case of the design of the seat 18 (see figure 3) with a magnet 21 in its composition, when the valve 8 is gripped, the magnetic field lines act on the valve 8 and the seat 18, increasing the gripping force, which, in turn, significantly increases the probability of failure-free operation and reliability of the installation during its operation.

In the case of the execution of the connection of the lower part of the rod 14 with the hammer 1 as a hydraulic damper (see figure 4), it becomes possible to smoothly transfer the weight of the hammer 1 to the connection of the valve 8 with the plunger 6 (see figure 1). At the beginning of the upward stroke, only the plunger 6 and valve 8 rise with the rod 14, and the hammer 1 remains stationary. Heel 23 is moving up. The load due to the weight of the hammer 1 is gradually transferred to the rod 14, due to the partial overlap of the holes 29 and only after the holes have completely overlapped 29 does the hammer 1 rise up. This eliminates the risk of a sharp separation of the plunger 6 from the valve 8 at high fluid rates. At the same time, the presence of a movable connection of the rod 14 and the hammer 1 allows you to repeatedly reduce the shock loads on the rod 14 that occur when the plunger 6 falls on the valve 8. The holes 28 and 29 also serve to eliminate the piston effect when the rod 14 moves with the fifth 23 in cavity 24 of the striker 1. When the heel 23 moves upward relative to the striker 1, the liquid located above the heel 23 is displaced through the openings 29 into the well 2, and the liquid from the well 2 is sucked through the openings 28 into the cavity 24. When the heel 23 moves downward relative to the striker 1, the liquidfrom the well 2 it enters the cavity 23 through the openings 29, and the liquid under the heel 23 exits through the openings 28 into the well 2. Therefore, there is practically no pressure difference between the regions above and under the heel 23, which eliminates the piston effect that slows down the movement of the heel 23 .

Thus, the proposed technical solution can significantly improve the reliability and MTBF of the installation for vibroseismic impact on the reservoir in comparison with the known inventions.

Claims (4)

1. Installation for vibro-seismic impact on the reservoir, characterized in that it contains a hammer for striking, located in the wellbore lifting device associated with the hammer, and the anvil, and the lifting device is made in the form of a housing in which a plunger with a passage channel is located, a centralizer-limiter for raising the hammer, made in the form of a sliding bearing with bore holes, and a valve with a seat, while the valve is connected to a rod connected to the hammer through a hydraulic damper The space between the outer surface of the housing of the lifting device and the inner surface of the well is blocked by the packer, and the space above the plunger of the lifting device is hydraulically connected to the suction line of the downhole pump. 2. Installation according to claim 1, characterized in that the plunger is collapsible. 3. Installation according to claim 1 or 2, characterized in that the seat is equipped with a magnet to provide additional pressure against the valve. 4. Installation according to claim 1 or 2, characterized in that the lower part of the rod is provided with a fifth, and in the upper part of the hammer there is a cavity with a cover in which a hole is made for the passage of the rod.

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