RU2206729C2 - Method and plant for vibroseismic stimulation of oil pool - Google Patents

Abstract

FIELD: oil producing industry; applicable in realization of vibroseismic shock stimulation for increase of oil recovery from formations. SUBSTANCE: method includes delivery of shocks by falling percussive tool onto formation concurrently with oil recovery from stimulated well. Percussive tool is lifted with help of piston due to use of flow energy of medium recovered from well. After each shock delivered onto formation by percussive tool, additional shock is delivered onto formation by falling piston through percussive tool. Plant for vibroseismic stimulation of oil pool has percussive tool for delivery of shocks, lifting device located in wellbore and connected with percussive tool, and anvil. Lifting device is made in form of body accommodating piston with through channel, valve and upper limiter of piston lifting. Space between external surface of lifting device body and well internal surface is closed with packer. Space above piston of lifting device is hydraulically communicated with suction line of oil-well pump. Valve is connected with percussive tool by means of rod and serves as lower limiter of piston falling. Percussive tool with rod and valve transmits energy of falling piston to anvil. Invention also offers various versions of plant design. EFFECT: higher reliability and extended functional potentialities of pool stimulation by delivery of additional shocks onto formation with provided rigid connection between valve and percussive tool. 8 cl, 4 dwg

Description

 The invention relates to the oil industry and can be used for vibroseismic shock to enhance oil recovery.

 A known method of striking a falling downhole projectile against a formation exposed by an exciting well using hydraulic energy to lift a downhole projectile and a device for its implementation, comprising a downhole projectile for striking, located in the wellbore, a lifting device associated with a downhole projectile, an interruption tool projectile and anvil (RF patent 2106471, CL E 21 B 28/00, 1998). The known method and device have low functionality and a limited scope because of the need to stop oil production from an exciting well for the entire period of exposure.

 Closest to the claimed invention are a method of vibro-seismic impact on a reservoir, including applying impacts by a falling bottom hole to the reservoir simultaneously with oil production from an exciting well and raising the bottom hole using a piston by using the energy of the medium flow extracted from the well, and an installation for its implementation comprising a downhole impact tool, a lifting device located in the wellbore associated with the downhole tool and an anvil, the lifting device The device is made in the form of a housing in which a piston with a passage channel, a valve and an upper piston lift limiter are located, while the space between the external surface of the lifting device housing and the internal surface of the well is closed by the packer, and the space above the piston of the lifting device is hydraulically connected to the suction line of the well pump (RF patent 2164287, class E 21 B 28/00, 43/25, 2001). The known method and 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 bottom hole with the help of a flexible rope, which was repeatedly torn during the bench tests. In addition, due to the flexible connection between the valve and the bottom hole, the piston, 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 piston at the very beginning of the up stroke due to the abrupt transfer of the weight of the bottom hole to the valve. The installation completely lost its operability.

 The objective of the invention is to increase reliability and expand the functionality of impact on the reservoir by applying additional blows to the reservoir while providing a tight connection between the valve and the bottom hole.

 Improving the reliability and expanding the functionality in the method of vibro-seismic impact on the reservoir is achieved by the fact that after each impact on the formation with a downhole projectile, they apply an additional blow to the formation by a falling piston through the bottom hole.

 Improving the reliability and expanding the functionality in the installation for vibro-seismic impact on the reservoir is achieved by the fact that the valve is connected to the bottom hole by means of the rod and is the lower limiter for the piston to fall, and the bottom hole with the rod and valve serves to transfer the energy of impacts of the falling piston to the anvil.

In an embodiment, the angle of taper of the valve is in the range from 1 to 10 ^o . This condition provides an effective conical grip and allows you to multiply increase the clutch reliability between the valve and the piston when lifting the downhole projectile.

 In one embodiment of the device, a centralizer is installed on the stem under the valve to ensure that the valve and piston are aligned at the moment of engagement.

 In another embodiment, levers are mounted on the valve to create additional force to open the valve, while the piston is provided with an emphasis for levers. This makes it possible to quickly and reliably open the valve at the top of the lift without creating an excessive pressure drop.

In one installation option, the working part of the upper piston lift limiter is made in the form of a hemisphere, and the lower surface of the stop is a cone with an angle in the range from 30 to 55 ^o . This allows you to get the most optimal ratios of the shoulders of the levers and reduce the effect of the degree of wear of the valve on its performance.

 In the installation options, the connection of the lower part of the stem with the bottom hole is made movable, the lower part of the stem being provided with a fifth, and in the upper part of the bottom hole 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 stem and the cover. In the cavity of the upper part of the bottom hole, holes can also be made connecting the cavity with the space of the well. This allows you to smoothly transfer the load from the weight of the downhole projectile to the piston of the lifting device at the beginning of the upward stroke and eliminates the risk of a sharp separation of the piston from the valve. The presence of a compression spring, in addition, makes it possible to further push the valve away from the piston at the beginning of the downward stroke after opening the valve and to ensure that the downhole projectile falls faster than the piston. The holes in this case serve to eliminate the piston effect when the rod moves with the fifth relative to the bottom hole.

 The specified set of distinctive features of the claimed invention allows to apply additional blows to the formation while significantly increasing the reliability and expanding the functionality of the impact.

 Figure 1 presents the installation diagram for vibroseismic impact on the reservoir, figure 2 shows a close-up of the valve to ensure effective conical capture, figure 3 - valve with levers, figure 4 is a variant of the connection of the lower part of the stem with the bottom hole.

 Installation for vibroseismic impact on the reservoir (see figure 1) contains a downhole tool 1 for striking, located in the wellbore 2 lifting device 3, connected with the downhole tool 1, and the anvil 4. The lifting device 3 is made in the form of a housing 5, which contains a piston 6 with a passage channel 7, a valve 8 and an upper limiter 9 for lifting the piston 6, 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 piston 6 is lifted many devices 3 are hydraulically connected to the suction line 12 of the downhole pump 13. The valve 8 is connected to the bottom hole 1 by means of the rod 14 and is the lower limiter for the fall of the piston 6, and the bottom hole 1 with the rod 14 and valve 8 are used to transmit the energy of the impacts of the falling piston 6 on the anvil 4. The anvil 4 is connected using the element 15 (for example, a cement bridge) with the formation 16.

Figure 2 presents a diagram of a valve, the taper angle of the outer surface 17 of which is in the range from 1 to 10 ^° in order to ensure effective conical gripping when the piston 6 is engaged with the valve 8. A centralizer 18 is mounted on the stem 14 under the valve 8.

On the valve 8 can be installed levers 19 to create additional efforts to open the valve 8 (see figure 3). The piston 6 is provided with a stop 20 for levers 19, which can be rotated on the axles 21. The levers 19 on the axles 21 are connected to the valve 8 by means of the holders 22. The working part of the upper limiter 9 for raising the piston 6 can be made in the form of a hemisphere, and the lower surface of the stop 20 thus represents a cone with an angle α (see figure 3) in the range from 30 to 55 ^o .

 The connection of the lower part of the rod 14 with the downhole projectile 1 can be made movable (see figure 4). The lower part of the rod 14 is provided with a fifth 23, and in the upper part of the bottom hole 1 there is a cavity 24 with a cover 25, in which there is a hole 26 for the passage of the rod 14. Between the fifth 23 of the rod and the cover 25, a compression spring 27 is installed. The cavity 24 of the upper part bottom hole 1 can be holes 28 and 29 connected to the space of the well 2.

 The method of vibroseismic impact on the reservoir according to the present invention is as follows.

 The falling downhole projectile 1 strikes the anvil 4. The energy of the impacts is transmitted through element 15 to the reservoir 16, creating oscillations in it. The bottom hole 1 is raised using the piston 6, using the energy of the medium flow extracted from the well 2 by the pump 13. After each impact on the formation 16, the bottom hole 1 inflicts an additional blow on the formation 16 through the downhole piston 6 through the bottom hole 1 with the rod 14 and valve 8, and also through the anvil 4 and element 15. At the same time, oil production from the exciting well 2 does not stop. The production of the well 2 is pumped further by the pump 13 to the surface.

 Thus, due to the application of additional shocks, the intensity of fluctuations in the reservoir increases, which contributes to enhanced oil recovery.

 Installation for vibroseismic effects on the reservoir works as follows.

 The bottom hole 1 is lifted by using the hydraulic energy of the medium extracted from the well 2. The pump 13 pumps out the production of the well 2 from the formation 16 to the surface through the suction line 12. 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 piston 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 piston 6 and closes the passage channel 7. The piston 6 with the valve 8 begins to move upward under the influence of the borehole medium and raises the downhole tool 1 connected to the valve 8 through the rod 14.

 When lifting the piston 6 with the downhole tool 1 to the highest position, the valve 8 abuts against the upper limiter 9 for lifting the piston 6. The valve 8 opens and the downhole tool 1 falls on the anvil 4. The piston 6 falls down after the arrangement, including the downhole tool 1 , the rod 14 and the valve 8. In this case, the downhole fluid flows freely through the passage channel 7 upward. After striking the anvil 4 and the formation 16 with the downhole projectile 1, the piston 6 falls on the valve 8. In this case, the piston inflicts an additional blow on the formation 16 through the valve 8, the rod 14, the bottom hole 1, the anvil 4 and the element 15, which is rigidly connected to the formation. channel 7 is thus blocked. Then, under the pressure of the borehole fluid, the piston 6 and the valve 8 move upward, raising the downhole tool 1 to the extreme upper position, by the rod 14, etc.

 Such repeated cycles of lifting, falling and striking with a downhole projectile 1 and a piston 6 make it possible to maintain intense vibrations in the formation 16. 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 taper angle of the outer surface 17 of the valve 8 in the range from 1 to 10 ^o (see figure 2) there is a significantly more effective engagement of the valve 8 with the piston 6 when the piston 6 falls on the valve 8, which increases the reliability of the installation. This also contributes to the centralizer 18, which allows for a tight, without distortion, landing of the piston 6 on the cone of the valve 8.

When the levers 19 are mounted on the valve 8 and the piston 6 is equipped with an emphasis 20 for the levers 19 (see FIG. 3), the force required to open the valve 8 in its highest position is reduced. This decrease is proportional to the ratio of the shoulders of the lever a and b. The reaction force of the upper limiter 9 acts on the levers 19, which rotate around the axes 21 on the holders 22 and push off from the stop 20, opening the valve 8. The working part of the upper limiter 9 of lifting the piston 6 in the form of a hemisphere and the lower surface of the stop 20 in the form of a cone with an angle α (see figure 3) in the range from 30 to 55 ^o allows you to get the most optimal ratios of the shoulders a and b of the levers 19, as well as reduce the influence of the degree of wear of the valve 8 on its performance.

 When connecting the bottom of the rod 14 to the bottom hole 1 movable (see figure 4), it becomes possible to smoothly transfer the weight of the bottom hole 1 to the connection of the valve 8 with the piston 6. At the beginning of the stroke, only the piston 6 and valve 8 with the rod 14 rise and downhole projectile 1 remains stationary. The heel 23 moves upward, compressing the spring 27. The load from the weight of the downhole projectile 1 is gradually transferred to the rod 14, and only after a certain compression of the spring 27 the lifting of the projectile 1 upwards begins. This eliminates the risk of a sharp separation of the piston 6 from the valve 8 at high fluid rates.

 The presence of a compression spring 27, in addition, allows, at the beginning of the down stroke after opening the valve 8, to further push the valve 8 away from the piston 6. This ensures a faster fall of the downhole projectile 1 compared to the piston 6. The spring 27 is unclenched and the heel 23 is lowered to its lowest position, in contact with the bottom of the cavity 24 in the upper part of the bottom hole 1. Therefore, when a piston 6 strikes the valve 8, the impact energy is transmitted through the heel 14 of the rod 14, which is rigidly in contact with the bottom hole 1, to the anvil 4 with the element 15 and then to the formation 16.

 Holes 28 and 29 are used to eliminate the piston effect when the rod 14 moves with the fifth 23 in the cavity 24 of the bottom hole 1. When the heel 23 moves upward relative to the bottom hole 1, the liquid located above the fifth 23 is displaced through the holes 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 bottom hole 1, the liquid from the well 2 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, the differential d phenomenon between the areas above and under the heel 23 is virtually absent, which eliminates the piston effect of retarding the movement of the heel 23.

 Thus, the proposed technical solution can significantly increase the reliability and expand the functionality of the vibroseismic effect on the reservoir compared with the known inventions.

Literature
1. RF patent 2106471, E 21 B 28/00, 1998.

 2. RF patent 2164287, E 21 B 28/00, 2001 (prototype).

Claims (8)

 1. The method of vibroseismic impact on the reservoir, including striking with a falling downhole projectile along the formation simultaneously with oil production from the exciting well and raising the bottomhole using the piston by using the energy of the medium flow extracted from the well, characterized in that after each impact on the formation downhole projectile inflict an additional blow to the reservoir with a falling piston through the downhole projectile.  2. Installation for vibro-seismic impact on the reservoir, containing the bottom hole for striking, located in the wellbore lifting device associated with the bottom hole, and the anvil associated with the reservoir, and the lifting device is made in the form of a housing in which there is a piston with a passage channel , a valve and an upper piston lift limiter configured to abut a valve therein, the space between the outer surface of the housing of the lifting device and the inner surface of the well blocked by the packer, and the space above the piston of the lifting device is hydraulically connected to the suction line of the downhole pump, characterized in that the valve has a taper angle of the outer surface, is connected to the bottom hole by means of the rod and is the lower limiter for the piston to fall, and the bottom hole with the rod and valve serve to transfer the energy of the impacts of the falling piston to the anvil. 3. Installation according to claim 2, characterized in that the taper angle of the outer surface of the valve is in the range from 1 to 10 ^o .  4. Installation according to claim 2 or 3, characterized in that a centralizer is installed on the stem under the valve.  5. Installation according to any one of claims 2 to 4, characterized in that levers are installed on the valve to create additional force to open the valve, while the piston is equipped with an emphasis for levers. 6. Installation according to any one of paragraphs.2-5, characterized in that the working part of the upper piston lift limiter is made in the form of a hemisphere, and the lower surface of the stop is a cone with an angle ranging from 30 ^o to 55 ^o .  7. Installation according to any one of claims 2 to 6, characterized in that the connection of the lower part of the stem to the bottom hole is made movable, the lower part of the stem is provided with a fifth, and in the upper part of the bottom hole there is a cavity with a lid in which there is an opening for passage rod, while between the fifth rod and the cover is installed compression spring.  8. Installation according to claim 7, characterized in that the cavity of the upper part of the bottom hole is connected to the space of the well by openings.

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