WO2022093066A1 - Submersible oil production assembly - Google Patents

Abstract

The invention relates to oil production equipment, can be used for lifting borehole fluid and provides for more reliable operation of a submersible oil production assembly by increasing the oil-filled volume of a hydromechanical drive, reducing the pulsations of an elastic membrane, and also reducing the cyclic load on the dynamic assemblies of a roller screw drive. A submersible oil production assembly comprises a plunger pump, the rod of which is sealed inside the pump housing, and a hydromechanical drive comprising an oil-filled housing, a roller screw drive of the screw and nut type, a perforated hollow rod surrounding the screw of the roller screw drive, said rod being connected to the rod of the plunger pump and being situated during its working stroke in the housing of the plunger pump, a hydraulic unit containing a hydraulic motor that is connected via a hydraulic distribution valve to an oil pump, the input shaft of which has an elastic membrane mounted thereon, and also hydromechanical dampers, one of which is rigidly fastened to the lower face of the nut of the roller screw drive, and the other of which is mounted between the oil-filled housing and the hollow rod of the drive such as to be capable of coming into contact with the nut of the roller screw drive in its uppermost position.

Description

Submersible oil production unit.

The field of technology.

The invention relates to oil-producing equipment and can be used to lift well fluid.

prior art.

Known submersible pumping unit containing a pumping unit, which includes a housing, an elastic shell, a reversible motor, the drive shaft of which is connected to the transmission screw of the rolling screw-nut, which is in a movable connection with the housing and connected to the plunger pump drive rod. The rod is sealed in the body and connected to the nut by means of a hollow cylindrical rod, enclosing the screw and entering into a movable connection with it, and the internal cavities of the body and the elastic shell are filled with oil. The outer surface of the shell communicates with the cavity of the well, and dampers in the form of springs are installed on the screw and the hollow rod. (Patent of the Russian Federation No. 2347947, published on February 27, 2009)

The reversible motor used in this design is multi-pole (low-speed), the main disadvantages of which are the complexity of the design and the decrease in the reliability of its operation. Switching the direction of rotation of the screw is carried out by a control station, which has a rather high cost. In addition, the fuzzy operation of the engine reverse due to the variable viscosity of the oil fluid reduces the efficiency of the installation, and also reduces the reliability of its operation. Increasing the accuracy of determining the time of switching the engine to reverse motion requires additional telemetry, which also leads to an increase in the cost of the installation. To increase the reliability of the installation, as well as to reduce its cost, the use of a hydromechanical drive of a special design makes it possible.

A submersible pumping unit is known, comprising a plunger pump, an electric motor with hydraulic protection and a hydromechanical drive, including a mechanical transmission of the "screw-nut" type connected to the plunger pump, a hydraulic unit, including a hydraulic motor, connected through a hydraulic distributor fixed to it, which regulates the direction of rotation of the screw of the mechanical transmission, with an oil pump, and an elastic membrane, which is a compensator for the volumetric expansion of the oil, while the upper part of the screw has a sliding support that freely moves along the inner diameter of the hollow piston. (Patent of the Russian Federation No. 184849, published on November 12, 2018).

In a known installation, the hydromechanical drive cavity is filled with hydraulic oil, while the hollow rod is sealed in the drive housing, thereby limiting the oil-filled volume within the housing. During operation of the unit, insufficiently efficient heat exchange of oil with formation fluid, due to a rather limited oil-filled volume of the drive, can lead to oil overheating, which, in turn, reduces the reliability of both the drive itself and the entire oil production unit as a whole.

In addition, the elastic membrane is a compensator for changes in the oil-filled volume caused by the reciprocating movement of the hollow rod. During the extension of the stem, the membrane is compressed, when the stem returns, it is stretched. The greater the variable volume (quantitatively, the variable volume is equal to the internal volume of the hollow rod) perceived by the membrane, the more intense its wear. Wear, in turn, leads to depressurization of the oil circuit and the failure of the entire installation. Another disadvantage of the known device is the absence of damping devices that allow the hollow rod to slow down in the extreme positions of its stroke. The absence of damping devices leads to an increased cyclic load on the dynamic components of the mechanical part of the hydromechanical drive, which, in turn, leads to a decrease in its resource indicators and drive failure.

The essence of the invention.

The task to be solved by the claimed invention is to increase the reliability of the operation of a submersible oil-producing installation by increasing the oil-filled volume of the hydromechanical drive, reducing the pulsations of the elastic membrane, and also reducing the cyclic load on the dynamic components of the roller screw drive.

The technical result is achieved by the fact that in a submersible pumping unit containing a submersible electric motor with hydraulic protection, a plunger pump and a drive, including an oil-filled housing with a screw-nut-type roller-screw transmission placed in it, a hollow rod enclosing the screw of the roller-screw transmission and connected to the plunger pump rod, a hydraulic unit, including a hydraulic motor connected to the roller-screw drive screw and connected through a hydraulic distributor to the oil pump, on the output shaft of which an oil volume expansion compensator is installed, made in the form of an elastic membrane, the plunger pump housing is made with the possibility of accommodating there is a hollow drive rod in it for the length of its stroke, and the hollow drive rod is made with perforation, and the plunger pump rod is sealed in the plunger pump housing, while the drive is equipped with hydromechanical dampers, one of which is rigidly fastened to the lower end surface of the roller screw drive nut cottages, and the other the damper is installed between the oil-filled housing and the hollow rod of the drive with the possibility of contact with the nut of the roller-screw transmission in its extreme upper position.

In addition, the perforation on the hollow rod is made from the side of the zone of connection of the hollow rod with the plunger pump rod, and the plunger pump rod is sealed in the plunger pump housing by means of a sealing sleeve.

The execution of the plunger pump housing with the possibility of placing a hollow rod of a hydromechanical drive in it for the entire length of its working stroke, sealing the plunger pump rod in the plunger pump housing and making a hollow rod with perforation, provides an increase in the oil-filled volume, which in this case is limited by the place of sealing of the plunger pump rod in the plunger pump housing. Filling with oil of this volume is carried out through the perforation of the hollow rod. At the same time, the seal of the piston pump rod, in comparison with the seal of the hollow rod of the drive, makes it possible to reduce leakages that occur during resource wear, since the diameter of the plunger pump rod is smaller than the diameter of the hollow rod.

An increase in the oil-filled volume reduces the temperature of the working oil, which increases the service life of the hydromechanical drive, and also reduces the pulsations of the elastic membrane, which reduces its wear.

The presence of hydromechanical dampers makes it possible to smooth out shock loads in the extreme positions of the roller screw drive, thereby preventing the destruction of its threaded part.

List of drawings.

Figure 1 shows a diagram of a submersible installation with a plunger pump; figure 2 - enlarged place I figure 1; Fig.3 - place II of figure 1, figure 4 - place III of figure 1, figure 5 - place IV of figure 1. The submersible oil production unit contains a submersible electric motor 1 with hydraulic protection 2, a hydromechanical drive 3 and a plunger pump 4. The hydromechanical drive 3 contains an oil-filled housing 5, a roller-screw transmission 6 placed in it, made of the screw-nut type with an increased nominal dynamic load capacity, hollow rod 7 enclosing the screw 8 of the roller screw 6 and included with it in a movable connection and connected with the nut 9 of the roller screw 6, the hydraulic unit 10, which includes a displacement hydraulic motor 11, mainly an axial piston motor, connected through a hydraulic valve 12 and a safety valve 13 with an oil pump 14 of a volumetric type, mainly axial piston, connected to the shaft 15 of the submersible motor 1, as well as an elastic membrane 16 installed on the input shaft of the oil pump 14, which acts as a compensator for the volumetric expansion of the oil. The hollow rod 7 of the drive 3 is connected to the rod 17 of the plunger pump 4 and is made with perforations 18. The perforations are made in the rod 7 on the side of its connection with the rod 17 of the plunger pump (Fig.3). Preferably, the perforation is made near or on the end surface of the stem 7.

The body 19 of the plunger pump is made long enough to accommodate the hollow rod 7 in it for the entire length of its stroke. Rod 17 of the plunger pump is sealed in the body of the plunger pump 4 by means of a sealing sleeve 20 (figure 2).

A hydromechanical damper 21 is installed between the housing 5 and the hollow rod 7, including the housing 22 with throttle holes 23 for damping, the return spring 24, the piston 25 and the seals 26 of the damper surfaces (Fig.4). Another hydromechanical damper 27 of a similar design is rigidly attached to the lower end surface of the nut 9 of the screw transmission and includes a housing 28 with throttle holes 29, a damper return spring 30, a piston 31 and seals 32 of the damper surfaces (Fig.5).

The operation of the gearbox is as follows.

Before the installation is lowered into the well, the cavities of the electric motor 1 and hydraulic protection 2, as well as the housing 5 of the hydromechanical drive, are filled with oil corresponding to the operating and temperature conditions of the equipment.

When the unit is lowered into the well, the formation fluid fills the space between the elastomeric membrane 16 and the housing 5. Under the action of hydrostatic pressure, the valves of the plunger pump 4 on the suction and discharge lines open and the fluid through the intake filter fills the entire volume of the working chamber of the pump 4 to the level of the formation fluid in the well .

The rotation from the shaft of the submersible motor 1 is transmitted to the shaft of the pump 14, which through the hydraulic unit 10 alternately supplies oil under high pressure to one of the channels of the hydraulic motor 11, which converts the energy of the hydraulic oil flow into mechanical rotational energy, thereby providing periodic multidirectional rotation of the hydraulic motor 11. After hydraulic motor 11, hydraulic oil enters the internal low-pressure cavity of the hydraulic unit 10.

The screw 8 of the screw gear 6, rotating, drives the nut 9 of this gear. Due to the multidirectional nature of the rotation of the screw 8, the nut 9 performs periodic reciprocating movements and, since it is rigidly connected to the hollow rod 7, which in turn is attached to the rod 17 of the plunger pump 4, the rod 7 moves the pump plunger 4 connected to the rod 17 .When the rod 17 moves down the cavity of the pump 4 is filled with downhole fluid, and when moving upwards, on the contrary, the liquid is forced out of the cavity of the pump 4 into the tubing.

When the hollow piston 7 moves into the volume of the body 19 of the plunger pump 4, limited by the seal of the rod 17, oil enters through the perforations 18, completely filling the entire provided volume.

When the hollow piston 7 is moved to the extreme positions, the oil volume is compensated by changing the diameter of the elastomeric shell 16. In this case, shock loads in the extreme positions of the hollow piston 7 are smoothed out by hydromechanical dampers 21 and 27. contact of the damper 27 with the base of the mechanical part of the drive, formed by the end of the nipple for the hydraulic motor 11. The oil from the internal cavities of the damper 27 through the holes 29 throttles into the total oil-filled volume. The necessary “braking” force arises, causing the hydraulic distributor 12 to switch. After the switch occurs, and the nut 9 changes the direction of movement, the damper 27, due to the return of the spring 30, replenishes the internal oil-filled volume through the throttle holes 29 and acquires its original dimensions.

When the hollow rod 7 is moved to the extreme upper position, the nut 9 through the mating part reaches the end of the piston 25 of the damper 21, the internal oil-filled volume of which is throttled through the holes 23, a smoother process of the appearance of a “braking” force is organized. When the nut 9 moves down, the spring 24 allows you to restore the internal oil-filled volume of the damper 21.

Claims

Claim.

1. A submersible oil production unit, containing a submersible electric motor with hydraulic protection, a plunger pump and a hydromechanical drive, including an oil-filled housing with a screw-nut type roller-screw transmission placed in it, a hollow rod enclosing the roller-screw screw and connected to the plunger rod. pump, a hydraulic unit, including a hydraulic motor connected to a roller-screw drive screw and connected through a hydraulic distributor to an oil pump, on the input shaft of which an oil volume expansion compensator is installed, made in the form of an elastic membrane, characterized in that the plunger pump housing is made with the possibility of accommodating it contains a hollow drive rod for the entire length of its stroke, and the hollow rod is made with perforation, and the piston pump rod is sealed in the plunger pump housing, while the drive is equipped with hydromechanical dampers, one of which is rigidly fastened to the lower end surface of the roller screw nut transmission, and the other is installed between the oil-filled housing and the hollow rod of the drive with the possibility of contact with the roller screw nut in its extreme upper position.

2. Installation according to claim 1, characterized in that the perforation on the hollow rod is made from the side of the connection zone of the hollow rod with the plunger pump rod.

3. Installation according to claim 1, characterized in that the plunger pump rod is sealed in the plunger pump housing by means of a sealing sleeve.

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SUBSTITUTE SHEET (RULE 26)