RU2327034C2 - Method of productive strata wave processing and device for its fulfillment - Google Patents

Abstract

FIELD: mining engineering; oil recovery.

SUBSTANCE: device includes cylinder and located in it plunger with ability of axis movement, connected with external drive of out-in traverse by hauling with inner passage. Cylinder and plunger are installed with ability of creation of isolated underplunger passage. Plunger is made as canted glass with ports on side and frontal surfaces and fitted with air valve in draft channel, and bleed-off valve located on upper frontal part of plunger. Method includes installing and fixing in cased well of plunger pair and periodical hydrodynamical acting on layer with pressure changing in underplunger passage. It is packed off the layer and tubular annulus and jointed with atmosphere while upper plunger stripping. At the end of upper plunger stripping - with block of well filling liquid, while down plunger stripping this passage with tubular annulus.

EFFECT: oil recovery improvement.

5 cl, 2 dwg

Description

The present invention relates to mining industries associated with the production of fluid from wells during the development of deposits using submersible sucker rod pumps, and can be used to increase oil recovery in the operation of oil wells.

Known methods of increasing oil recovery by wave action on the reservoir, for example, according to the patent of Russian Federation No. 2136851 (IPC 6 ЕВВ 43/00, publ. 09/10/1999) and according to US patent No. 6015010 (IPC 7 Е21В 43/25, publ. 10.09. 1997). These methods use dynamic effects associated with the operation of submersible sucker rod pumps. During the reciprocating movement of the pump plunger under the action of an external drive located at the wellhead, for example, a rocking machine, the amplitude values of the force acting on the bottom of the well change, which is converted into elastic vibrations of the formation, providing increased oil recovery.

A disadvantage of the known technical solutions is the limited power of the generated elastic vibrations, due to the fact that the discharge of liquid under pressure in the plunger space and tubing is carried out in the bottomhole zone, which is constantly under the static pressure of the liquid column in the annulus. In this case, the amplitude change in the pressure on the bottom, and therefore the power of the wave action, is determined by the pressure difference in the tubing and the bottomhole zone, which with real parameters of the equipment used is only a fraction of the bottomhole pressure.

The closest technical solution for the combination of essential features and the achieved effect is the method according to the patent of the Russian Federation No. 2075596 (IPC Е21В 43/25, 28/00, 43/16, publ. 20.03.1997), which consists in the following. A cylinder is lowered into a cased production casing well on tubing and secured in the formation zone. A plunger connected to the rocking machine is placed in the cylinder, mounted with the possibility of its axial movement and exit from the cylinder in its highest position. After mounting the device and filling the well with liquid, the rocking machine is turned on. As the plunger moves upward, fluid is compressed in the tubing, and when the plunger approaches its extreme upper position, the compressed fluid is discharged from the tubing into the production string. At the time of fluid discharge, a shock wave forms in the production casing, which reaches the bottom of the well and causes elastic vibrations in the reservoir.

The disadvantage of this method, as well as the methods according to the patents of the Russian Federation No. 2136851 and US No. 6015010, is the low power of the generated elastic vibrations.

To implement the methods of wave action on the reservoir, various devices are used. A well-known sucker-rod pump according to the patent of the Russian Federation No. 2138620 (IPC 6 ЕВВ 43/00, publ. 09/27/1999), including a cylinder with a suction valve and a partition with holes, a plunger with a discharge valve, the movable part of which is equipped with a stepped shank with a through axial channel and additional discharge valve. The thick part of the stepped shank and the cylinder baffle are made in the form of a spool pair.

The device according to the patent of the Russian Federation No. 2138620 allows you to use the pump not only for pumping downhole fluids, before and for implosive stimulation.

A disadvantage of the known device, as well as the methods for the implementation of which it is used, is the limited power of the generated elastic vibrations.

A device is known according to the patent of the Russian Federation No. 2075596 (IPC 6 ЕВВ 43/25, 28/00, 43/16, publ. 03/20/1997), including a lifting mechanism in the form of a rocking machine, a string of tubing, a cylinder with a seat, mounted on the end of the tubing, a plunger installed in the cylinder with the possibility of axial movement and exit from the cylinder in the highest position, a centralizer installed between the tubing string and the cylinder, a charging device, a container and rods with a rod, one end of which connected to a rocking machine, and the other with a plunger.

The known device allows to increase the power of elastic vibrations in the deposits and to optimize the number of devices used while reducing the cost of manufacturing and maintaining the device.

The disadvantage of the device according to the patent of the Russian Federation No. 2075596 is the complexity of its design, and therefore, low reliability. In addition, like the device according to the patent of the Russian Federation No. 2138620, this device cannot exclude the effect of the pressure of the liquid column in the annulus to ensure the maximum value of the power of the generated elastic vibrations.

The technical problem solved in the present invention is to increase oil recovery by means of a high-energy impact through the well on the reservoir by creating the maximum possible difference in the fluid pressure transmitted to the reservoir that occurs during hydraulic shocks from periodic ups and downs of the column filling the well, carried out during the return translational movements relative to the plunger cylinder installed in the borehole associated with an external drive.

The problem is solved in that in a method of wave processing of a productive formation, including installing and securing a plunger pair in a cased hole, including a cylinder and axially displaced inside the plunger, connected by traction with an external drive, and periodically transmitted hydrodynamic action to the formation by pressure changes in the sub-plunger chamber formed by the cylinder and plunger, said sub-plunger chamber is sealed from the formation and annulus and communicate with the atmosphere when the plunger moves up, and at the end of the plunger move up - with a column of fluid filling the well, when the plunger moves down, this chamber with the annulus is communicated.

The above sequence of operations can significantly increase the power of the wave action on the reservoir due to the full use of the effect of the hydraulic shock of the column filling the well in the subplunger chamber, since before the hydraulic shock the pressure in it is equal to atmospheric.

It is advisable to select the parameters of the hydrodynamic effect on the face by applying liquids with different densities, changing the height of the column filling the well, the stroke of the plunger and the frequency of the actuator's impact on the plunger. This will further increase the power of the wave action and apply the method for various conditions for the development of specific reservoirs.

The device proposed for implementing the method of wave processing of a productive formation includes a cylinder and a plunger placed therein with the possibility of axial movement, which is connected to an external reciprocating drive by means of a thrust with an internal channel. Unlike the prototype, in this device, the cylinder and the plunger are installed with the possibility of forming an insulated sub-plunger chamber, and the plunger is made in the form of an overturned glass with windows on the side and end surfaces and is equipped with an air valve located in the draft channel and installed on the upper end part of the plunger overflow valve.

The air valve in the thrust channel will ensure that atmospheric air enters the sub-plunger chamber when the plunger moves up and, conversely, prevents liquid from entering this chamber into the thrust channel when the plunger moves down. Windows on the lateral surface of the plunger allow fluid to flow from the annulus to the subplunger chamber when the plunger approaches its extreme upper position. An overflow valve and windows at the end of the plunger provide fluid overflow from the sub-plunger chamber when the plunger moves down.

It is advisable to perform a thrust in the form of two elements interconnected by means of a coupling with a channel. The upper element, it is advisable to perform a solid, and placed on the side of the plunger lower element with an internal channel. In this case, the length of the lower element should be such as to ensure the coupling of the coupling with the atmosphere at any position of the plunger.

This will increase the strength of the upper element, for example, through the use of a steel rope with high bearing capacity. In this case, the proposed device can be used to work in deeper wells.

It is advisable to provide the cylinder of the device with an insulating packer.

The use of an insulating packer will isolate the reservoir from the annulus, thereby changing the height of the column of the fluid filling the well to obtain the necessary force to act on the reservoir, regardless of the in-situ pressure, which will significantly expand the scope of the proposed device.

The invention is illustrated by drawings, in which Fig. 1 shows a device for wave processing of a reservoir, and Fig. 2 shows plunger displacement and pressure changes in a sub-plunger chamber versus time.

The proposed method is implemented as follows.

A plunger pair is lowered into a cased hole 1 (Fig. 1) and secured, for example, with a liner, packer-anchor 2 or cement bridge, cylinder 3 in the zone of the reservoir 4, providing isolation from the reservoir and the annular space of the subplunger chamber 5 formed by the cylinder 3 and the plunger 6. The plunger 6 using a hollow rod 7, the inner channel of which in the upper part is constantly in communication with the atmosphere, is connected to an external drive 8, for example, a rocking machine, reciprocating motion. The well is filled with fluid to a design height of H _g .

In the initial state, the plunger 6 is in its lowest position, and the fluid pressure in the subplunger chamber 5 and the annulus 9 is the same and equal to ρgH _w , where ρ is the density of the fluid, g is the acceleration of gravity. At the beginning of the movement of the plunger 6 upward under the action of the actuator 8, the chamber 5 through the valve 10 and the thrust channel 7 is connected to the atmosphere and the pressure in it drops to atmospheric P _a , remaining unchanged along the entire path of the plunger, equal to hh ₀ (figure 2). At the moment of the exit of the windows 11 of the plunger 6 beyond the end 12 of the cylinder 3, the liquid is discharged from the annular space 9 into the chamber 5 and the pressure in it increases to the maximum Р _max = ρgH _w + ΔР, where ΔР is the pressure increment in the chamber due to the impact of the liquid stream speed V about the end face 13 of the chamber 5. The resulting force is transmitted to the reservoir 4, causing wave oscillations in it. The wave reflected from the end face 13 of the chamber 5 with a speed C moves up the borehole. Having reached the wellhead, the reflected wave changes its direction and strikes the end of the chamber 5. Then the process of movement of the shock wave is repeated, while pressure surges in the chamber 5 are reduced with each subsequent action.

This graphic process is illustrated in Fig. 2, where 1 is a graph of the movement of the plunger h, 2 is a graph of the pressure ρ in the chamber 5, t is the time, t _c is the cycle time, h ₀ is the plunger stroke when the chamber 5 communicates with the annulus 9 .

After reaching the upper end position and the subsequent plunger 6 stroke downward, the liquid from the chamber 5 through the windows 14 at the end of the plunger 6 and the overflow valve 15 is forced into the annulus 9. After lowering the plunger 6 to the lowermost position, the cycle repeats.

The proposed device for wave processing of the reservoir includes a cylinder 3 and a plunger 6 placed therein with the possibility of axial movement. The plunger 6 is connected to an external reciprocating movement drive 8 by means of a rod 7 with an internal channel. The cylinder 3 and the plunger 6 are installed with the possibility of forming an insulated sub-plunger chamber 5. On the lateral surface of the plunger 6 there are windows 11, and on its end surface - windows 14. An air valve 10 is located in the lower part of the internal channel of the thrust 7, and in the upper end part of the plunger 6 - overflow valve 15. The plunger can be made in the form of a continuous upper element 16 and the lower element 7 with an internal channel, interconnected by means of a sleeve 17.

The operation of the proposed device is described in an example implementation of the method of wave processing of the reservoir.

The optimal parameters of wave processing of the reservoir in each case are determined at the stage of commissioning according to the results of geophysical and field measurements.

Preliminary calculations show that for the proposed devices with a plunger pair diameter of 57 mm, a plunger stroke of 2.5-3.5 m and a traction force of rocking machines 80-100 kN when they are used for wave processing of oil reservoirs at a depth of up to 1500 m with a column height oil-water fluid (ρ = 900 ... 1000 kg / m) from 500 to 1500 m dynamic pressure ΔР, equal to ΔP≈ρVC by the formula of N.E. Zhukovsky, is 40 ... 80 mPa, and the maximum force on the end face of the sub-plunger chamber reaches 140 ... 200 kN, which is unattainable when using other known technical solutions. Efforts of this order, as shown by the results of pilot works at the oil fields of Bashkortostan, are guaranteed to provide an effective impact on the reservoir with a long-term (up to 3-8 months) increase in oil recovery by 20 ... 30%.

A particular advantage of the proposed method of wave processing of productive formations and a device for its implementation is the ability to use equipment, tooling, production technology, works that are widespread in oil production practice.

Claims (5)

1. A method of wave processing of a productive formation, including installing and securing a plunger pair in a cased hole, including a cylinder and axially displaced inside the plunger, connected by traction with an external drive, and periodically transmitted hydrodynamic action to the formation by changing the pressure in the cylinder and a plunger to the sub-plunger chamber, characterized in that said sub-plunger chamber is sealed from the formation and annulus and communicate with the atmosphere When the plunger moves up, and at the end of the plunger moves up, with a column of fluid filling the well, when the plunger moves down, this chamber with the annulus is communicated. 2. The method according to claim 1, characterized in that the parameters of the hydrodynamic effects are selected by applying fluids with different densities, changing the column height of the fluid filling the well, the stroke of the plunger and the frequency of the actuator's impact on the plunger. 3. A device for wave processing of a reservoir, including a cylinder and an axially displaced plunger, connected to an external reciprocating drive by means of a thrust with an internal channel, characterized in that the cylinder and plunger are installed with the possibility of forming an insulated sub-plunger chamber, and the plunger is made in the form of an overturned glass with windows on the side and end surfaces and is equipped with an air valve located in the draft channel and mounted on the top the end of the plunger overflow valve. 4. The device according to claim 3, characterized in that the thrust is made in the form of two elements interconnected by means of a sleeve with a channel, while the upper element is solid, and the lower element located on the plunger side is made with an internal channel, the lower element being made length, ensuring the coupling with the atmosphere at any position of the plunger. 5. The device according to any one of claim 3 or 4, characterized in that the cylinder is equipped with an insulating packer.

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