RU2258129C1 - Method and device to apply vibrator seismic action to oil pool - Google Patents

Abstract

FIELD: oil production, particularly vibration generating arrangements for boreholes or wells for stimulating production.

SUBSTANCE: method involves applying impacts to oil reservoir by falling bottomhole tool simultaneously with oil recovery from stimulating well. Bottomhole tool lifting is performed when recovered product flow pressure in area between lifting device and anvil is less than bubble-point pressure. Gas-and liquid mixture is extracted after lifting device by immersed pump with gas separator or by immersed pump-ejector system including immersed pump, gas separator and jet device with check valve installed at inlet thereof or by water-jet pump with check valve at inlet thereof or by gas-lift assembly.

EFFECT: increased efficiency due to increased speed of bottomhole tool falling, increased frequency and power of impacts applied to oil reservoir.

15 cl, 6 dwg

Description

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

A known method of vibroseismic impact on a reservoir, including applying impacts by a falling downhole projectile along the formation simultaneously with oil production from an exciting well and raising the downhole projectile using a piston by using the energy of the medium flow extracted from the well, and an installation for its implementation, comprising a downhole projectile striking, located in the wellbore lifting device associated with the bottom hole and the anvil, and the lifting 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 dressed, while the space between the outer surface of the lifting device housing and the inner surface of the well is 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 (RF patent No. 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.

Closest to the claimed invention are a method of vibro-seismic impact on a reservoir, comprising striking an incident downhole projectile along the formation through the anvil simultaneously with oil production from an exciting well and lifting the downhole projectile in a lifting device using a piston by using the energy of the medium flow extracted from the well, as well as the application of an additional blow by a falling piston, after each impact by a downhole projectile along the formation, and an installation for vibroseismic exposure, containing a downhole impact tool, located in the wellbore, a lifting device associated with the downhole tool and the anvil, 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, while the valve is connected to downhole projectile through the rod and is the lower limiter for the fall of the piston, and the downhole projectile with the rod and valve serve to transfer the energy of the impacts of the falling piston to the anvil (RF patent No. 2206729, cl. E 21 B 43/25, 28/00, 2003). The known method and device have low efficiency due to the limited rate of fall of the downhole projectile in the fluid, resulting in a low frequency and energy of impacts in the formation.

The objective of the invention is to increase the effectiveness of the impact on the reservoir by increasing the rate of fall of the downhole projectile, increasing the frequency and energy of impacts applied to the reservoir.

The increase in efficiency in the method of vibroseismic impact on the reservoir is achieved by the fact that the bottom hole is lifted and strikes are carried out at pressurized product flow pressures in the zone between the lifting device and the anvil less than the gas saturation pressure of the oil. The process of striking in this case is carried out in a gas-liquid mixture, the density of which is less than the density of the liquid. The rate of fall of the downhole shell increases at the same time, which increases the frequency and energy of impacts. In variants of the method, an increase in the effectiveness of the impact is also achieved by setting a pressure lower than the pressure of oil saturation at the bottom of the well, pumping the gas-liquid mixture from the well behind the lifting device by means of a submersible pump with a gas separator, a submersible pump-ejector system, a hydraulic drive, hydro-jet pump or using gas lift.

Improving the efficiency in the installation for vibroseismic impact on the reservoir is achieved by the fact that the anvil is mounted on a support, and the length of the support L obeys the ratio

where H _sat is the distance from the bottom of the well to the point at which the pressure of the pumped product stream is equal to the pressure of saturation of the oil with gas.

In an embodiment, the support is equipped with centralizers. This condition helps prevent bending of the support during impacts and provides efficient transmission of impact energy to the formation.

In other embodiments of the device, a submersible pump with a gas separator, a submersible pump-ejector system comprising a submersible pump, a gas separator and a jet apparatus, a hydraulic actuator, a hydraulic jet pump or a gas lift arrangement are located above the lifting device in a well. These varieties of downhole equipment make it possible to efficiently pump gas-liquid mixtures without interruption in supply at high gas contents, which ensures an uninterrupted process of raising and lowering the bottom hole in the gas-liquid mixture with delivering high-energy impacts to the formation.

In one of the installation options, a double-row elevator was lowered into the well. This eliminates the need for a packer and associated problems during well operation.

The specified set of distinctive features of the claimed invention makes it possible to significantly increase the speed of the downhole projectile, the frequency and energy of impacts in the reservoir, which increases the effectiveness of the impact.

Figure 1 presents the installation diagram for vibro-seismic impact on the reservoir, figure 2 is an installation option with centralizers on the support, figure 3 is an installation option equipped with a submersible pump with a gas separator, when working in the downhole pressure region lower than the saturation pressure, figure 4 is an installation option with a submersible pump-ejector system, figure 5 is an installation option with a water-jet pump, figure 6 is an installation option with a gas lift arrangement.

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, associated 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. The valve 8 is connected to the downhole tool 1 by means of the rod 10 and is the lower limiter for the fall of the piston 6, and the downhole tool 1 with the rod 10 and valve 8 are used for transmission ener ii strikes incident piston 6 on the anvil 4. The anvil 4 is connected via the element 11 (e.g., cement plug) from the formation 12. The anvil 4 is mounted on the support 13, the length of which obeys the relation (1). 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 14.

Figure 2 presents the installation diagram with centralizers 15 on the support 13.

In the well 2 above the lifting device 3, a submersible pump 16 with a gas separator 17 (see FIG. 3), a submersible pump-ejector system 18 containing a submersible pump 16, a gas separator 17 and an inkjet apparatus 19 with a check valve 20 can be located (see Fig. 4). In the well 2 above the lifting device 3 can also be placed a hydraulic drive pump that is resistant to the harmful effects of free gas, such as a hydraulic screw or hydraulic jet. 5 shows a water-jet pump 21 with a check valve 22 at the reception. The water-jet pump 21 is located on a two-row elevator 23 launched into the well 2. In addition, a gas-lift arrangement 24 can be placed above the lifting device 3 in the well 2 (see FIG. 6).

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

The falling downhole projectile 1 strikes the formation 12 through the anvil 4 simultaneously with oil production from the exciting well 2. The energy of the impacts is transmitted through element 11 to the formation 12, 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. After each impact on the formation 12, the bottom hole 1 inflicts an additional blow on the formation 6 through the downhole piston 6 through the bottom hole 1 with the rod 10 and valve 8, and through the anvil 4 and element 11, moreover, the lifting of the downhole projectile 1 and the application of blows by it is carried out at pressures of the flow of pumped products in the zone between the lifting device 3 and the anvil 4, less than the pressure of saturation of oil with gas. The production of the well 2 is then pumped to the surface by a submersible pump 16 with a gas separator 17 (see FIG. 3) or a submersible pump-ejector system 18 containing a submersible pump 16, a gas separator 17 and an inkjet apparatus 19 with a check valve 20 at the intake (see FIG. 4), or with a water-jet pump 21 with a check valve 22 at the intake (see FIG. 5), or with a gas lift assembly 24 (see FIG. 6).

Thus, due to the lifting of the bottom hole and its impact at pressures of the pumped product in the zone between the lifting device and the anvil, lower than the pressure of saturation of oil with gas, the rate of fall of the bottom hole increases, which increases the frequency and energy of the impacts. Also, an increase in the effectiveness of the effect is achieved due to the fact that a pressure lower than the saturation pressure of oil with gas is set at the bottom of the well, while pumping the gas-liquid mixture from the well behind the lifting device by means of a submersible pump with a gas separator, a submersible pump-ejector system, a hydraulic drive, hydro-jet pump or with a gas lift.

Installation for vibroseismic effects on the reservoir works as follows.

The bottom hole 1 is lifted by using a gas-liquid mixture extracted from the well 2 to the surface using a submersible pump 16 with a gas separator 17 (see FIG. 3) or a submersible pump-ejector system 18 containing a submersible pump 16, a gas separator 17 and an inkjet apparatus 19 with a check valve 20 at the reception (see FIG. 4), or a water-jet pump 21 with a check valve 22 at the reception (see FIG. 5), or a gas lift assembly 24 (see FIG. 6).

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, then above the piston 6, which is in fluid communication with the suction line of the submersible pump 16 with the gas separator 17 (see Fig. 3) or the submersible pump-ejector system 18 (see FIG. 4), or a water-jet pump 21 (see FIG. 5), or a gas lift arrangement 24 (see FIG. 6), a vacuum is created. 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 under the influence of the borehole medium, the pressure of which is less than the saturation pressure of the gas, starts to move up and lifts the bottom hole 1 connected to the valve 8 through the rod 10 .

When lifting the piston 6 with the downhole projectile 1 to the extreme upper position, the valve 8 abuts against the upper limiter 9 for lifting the piston 6.

The valve 8 opens and the downhole projectile 1 falls on the anvil 4. The piston 6 falls down after the arrangement, including the downhole projectile 1, stem 10 and valve 8. The gas-liquid mixture freely flows through the passage 7 upward. After striking the anvil 4 and the formation 12 with a downhole projectile 1, the piston 6 falls on the valve 8. In this case, the piston inflicts an additional blow on the formation 12 through the valve 8, the rod 10, the bottom hole 1, the anvil 4 mounted on the support 13, the length of which obeys relation (1), and element 11 rigidly connected to the formation. The passage channel 7 is thus blocked. Then, under the pressure of the borehole fluid, the piston 6 and valve 8 move upward, raising the downhole tool 1 by the rod 10 to its highest position, etc.

Such repeated cycles of lifting, falling and striking with a bottom hole 1 and piston 6 can maintain high frequency and impact energy in the reservoir 12 due to the high rate of fall of the bottom hole 1. Oscillation processes in the formation 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 anvil 4 mounted on the support 13 with centralizers 15 (see Fig. 2), the length of which obeys relation (1), this condition prevents the bending of the support during impacts and ensures efficient transmission of impact energy to the formation.

When installed in the well 2 above the lifting device 3 of a submersible pump 16 with a gas separator 17 (see Fig. 3), a gas-liquid mixture is produced from the reservoir 12. The use of a submersible pump 16 with a gas separator 17 allows you to effectively separate the gas from the gas-liquid mixture, which leads to optimal operation of the submersible pump 17, and this, in turn, increases the reliability of the installation.

When installed in the well 2 above the lifting device 3, a submersible pump-ejector system 18 containing a submersible pump 16, a gas separator 17 and an inkjet apparatus 19 with a check valve 20 at the intake (see Fig. 4), a gas-liquid mixture is received from the reservoir 12 The use of a pump-ejector system 18 can increase the efficiency compared with the operation of a submersible pump 16 with a gas separator 17 (see figure 3). The presence of two suction lines of the pump-ejector system 18 - at the intake of the submersible pump 17 and at the intake of the jet pump 19 allows the well 2 to be operated in a wide range of flow rates and with an increased gas content of the produced well products, which increases the reliability of the installation.

When installing in the well 2 above the lifting device 3 of the hydro-jet pump 21 with a check valve 22 at the intake, lowered into the well 2 on a two-row elevator 23 (see Fig. 5), the production of well products coming from the formation 12 occurs with increased values of free gas and mechanical impurities. The use of a water-jet pump 21 increases the reliability of the installation in difficult operating conditions of the well 2, associated with the operation of the well without a packer and associated problems, the release of free gas from the reservoir 12, an increased content of colloidal particles in the well products, low productivity, etc.

When installing in the well 2 above the lifting device 3 of the gas lift arrangement (see Fig. 6), the production of well products from the reservoir 12 with increased gas content occurs. The use of a water-jet pump 21 increases the reliability of the installation in difficult operating conditions of the well 2, which increases the reliability of the installation.

Thus, the proposed technical solution can significantly increase the effectiveness of the vibroseismic effect on the reservoir in comparison with the known inventions.

Claims (15)

1. A method of vibro-seismic impact on a reservoir, including striking an incident downhole projectile along the formation through an anvil simultaneously with oil production from an exciting well and raising the downhole projectile in a lifting device using a piston by using the energy of the medium flow extracted from the well, as well as applying additional impact by a falling piston, after each impact by a downhole projectile across the formation, characterized in that the upset of the downhole projectile and inflicting blows by it is carried out at pump downstream pressures products in the area between the lifting device and the anvil, less than the pressure of saturation of oil with gas. 2. The method according to claim 1, characterized in that the pressure at the bottom of the well is set lower than the pressure of saturation of oil with gas. 3. The method according to claim 1 or 2, characterized in that the pumping of the gas-liquid mixture from the well behind the lifting device is carried out by a submersible pump with a gas separator. 4. The method according to claim 1 or 2, characterized in that the pumping of the gas-liquid mixture from the well behind the lifting device is carried out by a submersible pump-ejector system. 5. The method according to claim 1 or 2, characterized in that the pumping of the gas-liquid mixture from the well behind the lifting device is carried out by a hydraulic drive pump. 6. The method according to claim 5, characterized in that the pumping of the gas-liquid mixture from the well behind the lifting device is carried out by a hydro-jet pump. 7. The method according to claim 1 or 2, characterized in that the pumping of the gas-liquid mixture from the well behind the lifting device is carried out using a gas lift. 8. 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, 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 the piston lift limiter, while the valve is connected to the downhole projectile by means of the rod and is the lower piston fall limiter, and the downhole projectile with the rod and valve are used to transmit impact energy adayuschego piston on the anvil, wherein the anvil is mounted on a support, wherein the support length L obeys

where H _sat is the distance from the bottom of the well to the point at which the pressure of the pumped product stream is equal to the pressure of saturation of the oil with gas. 9. Installation according to claim 8, characterized in that the support is equipped with centralizers. 10. Installation according to claim 8 or 9, characterized in that in the well above the lifting device there is a submersible pump with a gas separator. 11. Installation according to claim 8 or 9, characterized in that in the well above the lifting device there is a submersible pump-ejector system containing a submersible pump, a gas separator and an inkjet apparatus. 12. Installation according to claim 8 or 9, characterized in that in the well above the lifting device there is a hydraulic pump. 13. Installation according to item 12, characterized in that in the well above the lifting device is placed a hydro-jet pump. 14. Installation according to claim 8 or 9, characterized in that a gas-lift arrangement is located in the well above the lifting device. 15. Installation according to any one of paragraphs.12-14, characterized in that a double-row elevator is lowered into the well.

Images