RU2646985C1 - Node for hydraulic protection of the submersible oil-completed electric motor (options) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to the field of oil production and can be used in installations for hydroprotection of submerged oil-filled electric motors for electric centrifugal pumps, used for production of formation fluid from wells. Unit for hydraulic protection of the submersible motor is designed for installation in the upper part of the engine from the pump side and contains a shaft, a head, thrust and radial bearings, an end seal, at least one compensation module. Module consists of two nipples connected by a cylindrical body, a compensating element, separating the compensating module into two cavities. Unit is provided with a device for forced movement of the compensating element, using the energy of the compressed gas. Device comprises a cavity hydraulically, connected to one of the cavities of the compensating module and constituting a closed region with it.

EFFECT: invention is aimed to increase the reliability and service life of the unit by avoiding the ingress of formation fluid into the chamber of the compensating element.

7 cl, 3 dwg

Description

The invention relates to the field of oil production and can be used in installations for hydraulic protection of submersible electric motors for electric centrifugal pumps used to produce formation fluid from wells.

A device is known for hydraulic protection of a submersible electric motor, comprising a shaft, thrust and radial bearings and at least one stage, which includes a cylindrical body, a pipe surrounding the shaft, coaxially mounted inside the cylindrical body to form an annular chamber bounded by the body and pipe, first and second nipples, at least one damping sleeve, at least one shaft seal and reciprocally mounted inside the annular chamber Nia annular piston therein and two annular elements formed by the annular end face of the piston in contact with the formation fluid in the form of segments of outer and inner tubes. In this case, the annular piston divides the annular chamber into two sections, one of which faces the second nipple, communicates with the annulus and is filled with its reservoir fluid, the other, facing the first nipple, is filled with dielectric fluid of the electric motor and is equipped with at least one supporting centering ring, at least one seal located at the contact point of the annular piston with the inner surface of the cylindrical body, and at least one seal at the contact point of the rings th piston with the outer surface of the pipe (according to patent RU 2513546, IPC F04D 13/10, published on 04/20/14).

A disadvantage of the known technical solution is the low reliability due to the complexity of synchronizing the movement of the annular piston and ring elements. In case of jamming of the piston or one of the elements, the movement of the entire damping system stops.

The closest technical solution (prototype) is a hydroprotector protector for a borehole pump electric motor, comprising a shaft, thrust and radial bearings and at least one stage, which includes a cylindrical body, a tube coaxially installed inside the tube, the first and second nipples, at least one damping sleeve, mechanical seal and annular piston mounted with the possibility of reciprocating motion in an annular chamber formed in the space between cyl an indrical casing and a tube, while dividing this annular chamber into two sections, respectively filled with dielectric and reservoir fluids coming from the annulus. The movable mechanical module included in the tread separating the reservoir fluid and the reservoir fluid coming from the annulus is an annular piston (according to the patent US 6307290, IPC H02K 5/132, F04D 13/08, published October 23, 01).

A disadvantage of the known technical solution is that during operation, scaling (reaction products of the walls of the annular chamber and a chemically active formation fluid) forms on the inner wall of the cylindrical body and the outer wall of the liner enclosing the annular chamber. Such formations significantly impede the movement of the annular piston within the corresponding section of the annular chamber, up to the complete jamming of the piston and, consequently, the failure of the tread. These processes cause increased wear on the inner surface of the housing and the outer surface of the sleeve due to friction arising between them, and, as a consequence, a decrease in the reliability of the tread.

The problem to which the invention is directed, is to increase the reliability and service life of the site by eliminating the ingress of formation fluid into the chamber of the compensating element.

Technical results include improving the reliability and service life of the unit for hydraulic protection of a submersible oil-filled electric motor (hereinafter referred to as hydraulic protection).

The indicated technical results are achieved using the options of the hydraulic protection unit of a submersible oil-filled electric motor.

According to one embodiment, a unit for hydraulic protection of a submersible oil-filled electric motor designed to be installed in the upper part of the electric motor from the pump side, comprising a shaft, a head, thrust and radial bearings, a mechanical seal, at least one compensating module, which includes two nipples, connected by a cylindrical body, a compensating element dividing the compensating module into two cavities, characterized in that the node is equipped with a device for forced movement element using compressed gas energy containing a cavity hydraulically connected to one of the cavities of the compensating module and making up a closed region with it.

At least one module comprising a nipple, a cylindrical body, a tube that is installed outside the shaft, and a gas refueling device is included in a device for forced movement of a compensating element using compressed gas energy.

The compensating element is made in the form of a piston.

The device for forced movement of the compensating element includes at least one module containing a nipple, a cylindrical body, a tube that is installed outside the shaft, hydraulically connected to one of the cavities of the compensating module through a channel in the nipple, and a metering device is installed in the channel gas into the compensating module to maintain a given pressure value in it.

A dynamic labyrinth is placed above the mechanical seal, including a dynamic sleeve that is mounted on the shaft, and the mechanical seal does not have a hydraulic connection with the cavity of the compensating module.

In another embodiment, a unit for hydraulic protection of a submersible oil-filled electric motor, designed to be installed in the lower part of the engine, in which there is no connection to the pump, comprising at least one compensating module, which includes two nipples connected by a cylindrical body, a compensating element, dividing the compensating module into two cavities, characterized in that the node is equipped with a device for forced movement of the compensating element using the energy of compressed gas, with holding cavity hydraulically connected to a compensation module and component cavities with it a closed area. In this case, the compensating element is made in the form of a piston.

Due to the fact that the device for forced movement of the piston is filled with a gaseous medium, which can change its volume as a result of a change in pressure, the operation of the compensating module is provided, which compensates for the temperature change in the volume of motor oil. The connection of the compensating module with the annulus filled with a chemically active reservoir fluid with mechanical impurities is excluded.

A device for dosed gas supply allows you to provide the necessary pressure drop across the mechanical seal.

A dynamic labyrinth prevents formation fluid from entering the area above the mechanical seal.

In addition to the piston, a bellows or an elastic membrane (diaphragm) can be used as a compensating element.

The invention is illustrated by figures, which depict:

FIG. 1 - site for hydraulic protection of the electric motor with a device for forced movement of the piston, mounted above the submersible motor.

FIG. 2 - site for hydraulic protection of the electric motor with a device for forced movement of the piston, mounted under the submersible motor.

FIG. 3 - a dynamic labyrinth.

Hydroprotection (Fig. 1) is installed above the submersible motor (not shown in the figure) and contains a shaft 1, a head 2, a thrust 3 and a radial 4 bearings and a compensating module, which includes a cylindrical housing 5, a guide rail 6 coaxially installed inside it, middle 7 and lower 8 nipples, annular piston 9, mounted with the possibility of reciprocating motion, mechanical seal 10, device for forced movement of the piston, consisting of a cylindrical body 11, coaxially mounted in put it on the tube 12, middle 7 and upper 13 nipples.

The annular piston 9 divides the compensating module into two cavities: the lower 14 and the upper 15, respectively filled with a dielectric (oil) and gas (air) medium. The upper cavity 15 is connected by a channel 16 with a metered gas supply device 17 with a cavity 18 of the device for forced movement of the piston. The lower nipple 8 is connected to the base 19.

A bump 20 is installed on the shaft 1.

Channel 21 is made in the lower nipple 8, and channel 22 in the base 17.

Channel 23 with plug 24, located in the lower nipple 27, serves to fill the hydraulic protection with oil (together with a submersible motor).

Channel 25 with plug 26 and valve 27, located in the middle nipple 7, is used for pumping into the device for forced movement of the air piston under the necessary pressure.

Hydroprotection (Fig. 2) is installed under the submersible motor (not shown in Fig.) And contains the upper 28 and lower 29 nipples connected by a cylindrical body 30. A piston 31 is located inside the body 30, separating two cavities: the lower 32 and the upper 33, filled respectively gas (air) and dielectric (oil) medium. A stop 34 is located on the lower nipple 29. A channel 35 is formed in the upper nipple 28, connecting the upper cavity 33 with the internal cavity of the electric motor.

Channel 36 with plug 37 and valve 38, located in the lower nipple 29, serves to pump into the lower cavity 32 of the device for forced movement of the air piston under the necessary pressure.

A dynamic labyrinth assembly is placed in the head 2, including a dynamic bush 39 (Fig. 3), rigidly mounted on the shaft 1, and a labyrinth bush 40, mounted on the upper nipple 13.

Hydroprotection installed above the electric motor operates as follows. Before lowering into the well, the device for hydraulic protection together with the submersible motor is filled with dielectric oil. Gas (air) is pumped into cavity 18. When the motor is turned on, the torque from the motor shaft is transmitted through the hydraulic protection shaft 1 to the shaft of the submersible centrifugal pump. Compensation of leakage of dielectric oil and thermal changes in its volume during operation of the electric motor and its shutdowns is carried out by changing the volume of the cavity 14 when moving the annular piston 9, while changing the volume of the cavity 15 filled with a gas (compressible) medium.

Protection against ingress of formation fluid into the electric motor is carried out using the mechanical seal 10.

When the shaft 1 of the pump rotates, the dynamic labyrinth also begins to rotate, part of which is the dynamic sleeve 39, rigidly connected to the shaft 1, while mechanical impurities are discarded to the periphery. Gas dissolved in the reservoir fluid accumulates in the upper part of the dynamic sleeve 39 and also prevents mechanical impurities from entering the area of the mechanical seal 10, which positively affects the reliability of the hydraulic protection.

Hydroprotection installed under the electric motor operates as follows. Before lowering into the well, the device for hydraulic protection together with the submersible motor is filled with dielectric oil. Gas (air) is pumped into cavity 32. Compensation of dielectric oil leaks and thermal changes in its volume during operation of the electric motor and its shutdowns is carried out by changing the volume of the cavity 33 when moving the piston 31, while the volume of the cavity 32 is changed by the filled gas (compressible) medium.

Thus, the solutions used in the invention increase the reliability of the hydraulic protection unit of a submersible oil-filled electric motor, eliminating the ingress of formation fluid into the chamber of the compensating element.

Claims (7)

1. An assembly for hydraulic protection of a submersible oil-filled electric motor designed to be installed in the upper part of the electric motor from the pump side, comprising a shaft, a head, thrust and radial bearings, a mechanical seal, at least one compensating module, which includes two nipples connected a cylindrical body, a compensating element dividing the compensating module into two cavities, characterized in that the node is equipped with a device for forced movement of the compensating element with using the energy of compressed gas containing a cavity hydraulically connected to one of the cavities of the compensating module and making up a closed region with it. 2. The node according to p. 1, characterized in that the device for forced movement of the compensating element using the energy of compressed gas includes at least one module containing a nipple, a cylindrical body, a tube that is installed outside the shaft, a device for refueling gas. 3. The node according to claim 1, characterized in that the compensating element is made in the form of a piston. 4. The node according to p. 1, characterized in that the device for the forced movement of the compensating element includes at least one module containing a nipple, a cylindrical body, a tube that is installed outside the shaft, hydraulically connected to one of the cavities of the compensating module through the channel in the nipple, and in the channel there is a device for dosed supply of gas to the compensating module to maintain a given pressure value in it. 5. The assembly according to claim 1, characterized in that a dynamic labyrinth is placed above the end seal, including a dynamic sleeve that is mounted on the shaft, and the end seal has no hydraulic connection with the cavity of the compensating module. 6. A unit for hydraulic protection of a submersible oil-filled electric motor, designed to be installed in the lower part of the engine, which has no connection to the pump, and containing at least one compensating module, which includes two nipples connected by a cylindrical body, a compensating element, dividing the compensating module into two cavities, characterized in that the node is equipped with a device for forced movement of the compensating element using the energy of a compressed gas containing a cavity Fluidly coupled to one of the compensation module and component cavities with it a closed area. 7. The node according to claim 6, characterized in that the compensating element is made in the form of a piston.

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