RU2724697C1 - Method of plunger depth pump valves serviceability restoration - Google Patents

Abstract

FIELD: oil and gas industry.SUBSTANCE: invention relates to oil and gas industry for cleaning valves in borehole sucker rod pumping units. To implement the plunger depth pump valves serviceability recovery valve, the subsurface pump wellhead drive operation is stopped. Movable structural elements of the pump are lifted by means of rods. Movable structural elements are lowered until they interact with fixed valves for cleaning and restoration of valves serviceability. First, the most efficient vibration frequency is determined for borehole conditions, providing for action on the seats and shutoff elements of the valves and enabling restoration of the valve operability. A resonator is selected from a durable and wear-resistant material which generates certain vibrations. Moving, moving or immovable structural elements of the pump are equipped with resonators before descent into the well by resonators providing generation of oscillations at interaction during cleaning of valves, to restoration of serviceability of valves.EFFECT: technical result is achieved – implementation of recovery of flotation ability and providing qualitative locking of valves without mechanical action on valves and use of external sources of flushing.7 cl, 3 dwg

Description

The invention relates to the oil and gas industry for cleaning valves in well sucker-rod pumping units.

A known method of ensuring the operation of the suction valve of a deep rod pump (patent RU No. 2258836, IPC F04B 47/00, publ. 08/20/2005 Bull. No. 23), which consists in the fact that the suction valve installed in the lower end of the cylinder in the form of a floating ball, located in the valve body above its seat, they are affected by the flow of produced fluid arising due to the pressure difference between the cavities separated by the suction valve, and when the suction valve is operating, the valve cavity is mechanically cleaned and the suction valve is forced to close by additional force, and in case of failure of the suction valve, its forced closure is carried out by mechanical action on it with the lower end of the plunger in combination with pacing the latter.

The disadvantages of the method are the narrow scope, as it is intended for cleaning only the suction valve, the complexity of maintenance and reduced efficiency associated with the need for structural changes to standard products, which leads to poor pump performance due to slower operation of the suction valve.

The closest in technical essence is a borehole sucker rod pump (patent SU No. 1525319, IPC F04B 53/14, F04B 47/02, publ. 11/30/1989) containing a cylinder, a plunger located in the cylinder cavity, suction and discharge valves installed respectively in the cavities of the cylinder and cylinder and equipped with a saddle, a locking element and a hollow cage, and the hollow cage of the suction valve is made coaxially with the hollow rod, and the hollow cage of the suction pump is mounted movably in the axial direction and is spring-loaded relative to its saddle, and from the lower end of its lower end the end face is provided with a protrusion located eccentrically to its axis, the surface of which faces the locking element, is oval, and the rod and the protrusion are installed with the possibility of interaction with the locking elements of the discharge and inlet valves, respectively, when lowering the rods down.

For this pump, a method of cleaning valves is carried out, including stopping the pump drive by expanding the headstock with a technological pipe on top of the column, lowering the hollow plunger with the help of rods to its lowest position until the locking element of the discharge valve interacts with the rod movably in the axial direction and the spring is pressed against the saddle by the suction valve cage , after squeezing the shut-off element of the discharge valve upward by the rod, the hollow plunger interacts with the cage with compression of the spring until the oval surface of the protrusion interacts with the shut-off element of the suction valve and is pressed to the side to provide direct flushing due to the through communication of the borehole pump cavities with the cavity of the pump pipe string and well.

The disadvantages of the method and device are the complexity of maintenance associated with the need to use pumping units, and a decrease in efficiency associated with the need to make structural changes to standard products, which leads to deterioration of the pump due to the slowdown of the suction valve, and mechanical action on the shut-off organs can lead to their failure.

The technical task of the alleged invention is to provide a method for restoring the functionality of the valves of a plunger deep-well pump, which allows mechanical patency to be restored and to ensure high-quality valve closure without mechanical impact on the valve shut-off bodies and the use of external flushing sources.

The technical problem is solved by the method of restoring the operability of the valves of the plunger deep pump, including stopping the operation of the wellhead drive of the deep pump, lifting the movable structural elements of the pump with the help of rods, lowering the moving structural elements to interact with the stationary ones to clean and restore the valves.

It is new that preliminary, for downhole conditions, the most effective oscillation frequency is determined, which provides an impact on the seats and locking elements of the valves and allows the valves to recover, select a resonator from a durable and wear-resistant material that generates certain vibrations, equip movable, fixed or movable and stationary structural elements of the pump with resonators, providing oscillation during interaction during valve cleaning, until the valves are restored to working condition.

Also new is the fact that when using an insert pump as a plunger deep pump, a locking support fixed inside the well is used as a fixed structural element, on top of which a resonator is installed, which is configured to interact with the cylinder of the deep pump.

Also new is the fact that when using an insert pump as a plunger deep pump, a cylinder of a deep pump is used as a movable structural element, from the outside of which a resonator is installed, which is configured to interact with a locking support fixed inside the well.

Also new is the fact that when using an insert pump as a plunger deep pump, a lock support fixed inside the well is used as a fixed structural element, on top of which a resonator is mounted, and as a movable structural element, a deep pump cylinder is used, from the outside of which a resonator is installed, and the resonators installed with the possibility of interaction when installing the cylinder in the castle support.

Also new is the fact that when lowering the cylinder of the deep pump as a part of the column of elevator pipes, a cylinder is used as a fixed structural element, on top of the suction valve of which a resonator is installed, which is configured to interact with the plunger of the deep pump.

It is also new that when lowering the cylinder of the deep pump as a part of the column of elevator pipes, a plunger is used as a movable structural element, from the bottom of which a resonator is installed, made with the possibility of interaction with a limiter located above the suction valve of the cylinder.

Also new is the fact that when lowering the cylinder of the deep pump as a part of the column of elevator pipes, a cylinder is used as a fixed structural element, a resonator is installed on top of the suction valve, and a plunger is used as a movable structural element, the resonator is installed at the bottom, and the resonators are made with the possibility of interactions when lowering the plunger into the cylinder.

In FIG. 1 shows a diagram of the implementation of the method when using a cylinder as part of an elevator pipe string.

In FIG. 2 shows a diagram of an implementation of a method with an insertable submersible pump.

In FIG. 3 shows an embodiment of the resonator.

Structural elements and technological connections that do not affect the implementation of the method are not shown in the figures or are shown conditionally.

The method is implemented in the following sequence.

In the well 1 (Fig. 1 and 2) in the installation interval, a plunger deep pump is lowered, consisting of a cylinder 2 with a suction valve 3 at the bottom and a hollow plunger 4 with a discharge valve 5 located at the bottom. In this case, the plunger 4 is connected by rods 6 (Fig. 1) with a wellhead drive (not shown). Wellhead drive (rocking machine, chain drive, hydraulic drive or the like) through the rods 6 transmits reciprocating motion to the plunger 4 (Fig. 1 and 2) When the plunger 4 moves downward in the cylinder 2 below the plunger 4 creates an excess pressure that closes a suction valve 3 and an opening discharge valve 5 for the flow of fluid from the sub-plunger cavity of the cylinder 2 into the supra-plunger. When the plunger 4 moves upward in the cylinder 2, a vacuum is created below the plunger 4, and a division is created by a liquid column above the plunger 4, as a result, the discharge valve 5 closes, raising the liquid column above the plunger 4 in the volume of the plunger cavity of cylinder 2, covered by the working stroke of the plunger 4, and the suction valve 3 opens to transfer fluid from the well to the sub-plunger cavity of cylinder 2. When the cycle is repeated, the well fluid is pumped to the surface by a downhole pump.

Most often I use two installation options for 1 deep-well pumps in the well:

1. When lowering the cylinder 2 (Fig. 1) of the deep pump as a part of the column of elevator pipes 7, cylinder 2 is used as a fixed structural element, and plunger 4 is used as a movable element.

2. When using an insert pump as a plunger deep pump (Fig. 2), a fixed support 11, used as an anchor (not shown in Fig. 2) with a packer 10, is used as a fixed structural element with a packer 10, and as a movable element, cylinder 2.

During operation, the seats 8 and 9 of the corresponding valves 3 and 5 and the valves 3 and 5 themselves become clogged (for example, clay mud, asphalt-tar deposits, corrosion products, etc.), which leads to a decrease in the efficiency of the downhole pump or its exit out of service. To clean valves 3 and 4 and seats 8 and 9, it was decided to use a wave action - mechanical vibration. As studies at the wells of the Republic of Tatarstan (RT) have shown, the waves with a frequency of 10-320 Hz are most effectively cleaned. For the generation of such frequencies, solid and wear-resistant tool steels U7 (hardness HRC 59 - 61) and X12MF (hardness HRC 56 - 59) were suitable from metals, from which it was decided to make resonators that were lowered into the depth pump. Since the plunger pump is a plunger pair: cylinder 2 (Fig. 1 and 2) and plunger 4 with installation threads (not shown) above and below, to which, respectively, seats 8 and 9 are connected with valves 3 and 5 of the rod 6 (Fig. 1) to plunger 4 and elevator pipes 7 (if available) to cylinder 2. Resonators decided to install using standard installation threads of a deep pump or in joints between structural elements. For example, the resonator 12 (Fig. 3), mounted at the bottom of the plunger 4 (Fig. 1) with a diameter of 48 mm and made of X12MF steel, is equipped with an installation thread 13 (Fig. 3) of the external 14 and internal 15 grooves to provide the necessary generated oscillation frequency. For other types of resonators, various designs, diameters, sawn from another material, etc. design may be different. For example, for installation between the couplings, a collar (not shown) can be cut from the outside, for attachment from above to the lock support 11 (Fig. 2) by an external lower thread (not shown), etc. There are many ways to connect resonators with a deep pump, and the authors do not claim this. For the manufacture of resonators, a sufficiently selected material processed on a lathe is sufficient, which is very cheap and practical. Resonators are very easily replaced with new ones in case of failure, facilitating maintenance. After descent, the depth pump is adjusted so that the resonators do not interact with anything during the operation of the depth pump.

Consider both installation options.

1. Before lowering into the well 1 (Fig. 1), a resonator 12 is installed from the bottom of the plunger 4 and / or a resonator 16 is installed above the suction valve 3 in the cylinder 2. When the valves 3 and / or 5 become clogged or malfunctioning, the wellhead drive is stopped by the rods 6 being lifted and build up with a technological pipe (not shown), which allows the plunger 4 to be lowered, which ensures that the necessary oscillations during the reciprocating movements of the rod 6 interact with the resonator 12 of the plunger 4 with the stop 17 or the resonator 16, or the resonator 16 with the plunger 4. To restore the valves 3 and 5 in 90% of cases, 3 to 5 collisions of the resonator (s) 12 and / or 16 are sufficient. In cases of failure to restore operability, the cleaning operation by vibrations of valves 3 and 5 is repeated until their operability is restored.

2. Before lowering into the well 1 (Fig. 2), a resonator 18 is installed on top of the lock support 11 and / or a resonator 19 is installed outside the cylinder 2. When the valves 3 and / or 5 become clogged or fail, the wellhead actuator stops the rods 6 (Fig. 1 ) lift to the interaction of the plunger 4 (Fig. 2) with the upper limiter (not shown) of the cylinder 2 and joint lifting until the lock 20 of the cylinder 2 is removed from the castle support 11 (determined by the reduction in the weight of the rods on the wellhead weight indicator - not shown). After that, the rods 6 (Fig. 1) together with the plunger 4 (Fig. 2) and the cylinder 2 are lowered to the entrance of the lock 20 into the castle support 11, providing for the generation of the necessary vibrations the interaction of the resonator 19 of the cylinder 2 with the castle support 11 or the resonator 18, or the resonator 18 with the cylinder 2. After that, the rise of the plunger 4 with the cylinder 2 is repeated to generate oscillations of the resonators 18 and / or 19. In 90% of cases, 2 to 3 collisions of the resonator (s) 18 and / or 19 are sufficient to restore the operability of valves 3 and 5 In cases of non-restoration of operability, the cleaning operation by oscillations of valves 3 and 5 is repeated until their operability is restored.

After the recovery of valves 3 and 5 (Figs. 1 and 2), everything is restored to its original state. The rods 6 are connected to the wellhead drive and put into operation to lift the fluid from the well 1 (Fig. 1 and 2) to the surface.

As practice has shown in 9 out of 10 (90%) cases, it is possible to restore the operability of valves 3 and 5 after the first cycle, in contrast to flushing valves 3 and 5 (60% success). At the same time, the overhaul period, requiring the extraction of the deep pump from well 1, has increased at least twice.

The proposed method of restoring the functionality of the valves of the plunger deep-well pump allows, without mechanical impact on the valves and the use of external flushing sources, to restore patency and ensure high-quality locking of the valves.

Claims (7)

1. The method of restoring the functionality of the valves of the plunger deep pump, including stopping the operation of the wellhead drive of the deep pump, raising the movable structural elements of the pump with the help of rods, lowering the moving structural elements to interact with the stationary ones for cleaning and restoring the valves, characterized in that it is preliminarily for downhole conditions determine the most effective frequency of oscillations, providing an impact on the seats and locking elements of the valves and allowing to restore the valves, select the resonator from a durable and wear-resistant material that generates certain vibrations, equip the moving, stationary or movable and stationary pump structural elements with resonators before lowering into the well, providing generation of oscillations during interaction during valve cleaning, until the valves are restored to serviceability. 2. The method according to p. 1, characterized in that when using the plug-in pump as a plunger deep pump as a fixed structural element, a lock support fixed inside the well is used, on top of which a resonator is installed, which is configured to interact with the cylinder of the deep pump. 3. The method according to p. 1, characterized in that when using an insert pump as a plunger deep pump, a deep pump cylinder is used as a movable structural element, from the outside of which a resonator is installed, which is configured to interact with the castle support fixed inside the well. 4. The method according to p. 1, characterized in that when using an insert pump as a plunger deep pump as a fixed structural element, a locking support fixed inside the well is used, on top of which a resonator is mounted, and a cylinder of a deep pump is used as a moving structural element, outside which set the resonator, and the resonators are installed with the possibility of interaction when installing the cylinder in the castle support. 5. The method according to p. 1, characterized in that when lowering the cylinder of the deep pump as part of the column of elevator pipes, a cylinder is used as a fixed structural element, a resonator mounted on top of the suction valve that is configured to interact with the plunger of the deep pump. 6. The method according to p. 1, characterized in that when lowering the cylinder of the deep pump as part of a column of elevator pipes, a plunger is used as a movable structural element, a resonator is installed at the bottom of it, which is configured to interact with a limiter located above the cylinder suction valve. 7. The method according to p. 1, characterized in that when lowering the cylinder of the deep pump as part of a column of elevator pipes, a cylinder is used as a fixed structural element, a resonator is installed on top of the suction valve, and a plunger is used as a movable structural element, on the bottom of which a resonator is installed moreover, the resonators are made with the possibility of interaction when re-lowering the plunger into the cylinder.

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