RU42864U1 - ELECTRIC HYDRAULIC DRIVE PUMP UNIT - Google Patents

Abstract

1. A borehole electrohydraulic drive pump unit containing a kinematically interconnected submersible motor and a drive oil pump communicated from the inlet side with an oil tank, a working pump with suction and discharge valves, with an actuator driven by a hydraulic motor, the cylinder cavities of which are connected through the distributor to the inlet and through a safety valve - with the output of the drive oil pump, the hydraulic motor rod through the tread is connected to the working pump rod, and the oil tank is connected to oil volume compensator and is made with an oil flow regulator and a filter, characterized in that the tread is made in the form of at least 2 located concentrically relative to the stem and separated by oil-filled cavities, and the oil volume compensator is made in the form of a cylinder, in which a piston is installed with the formation of a piston and a piston cavity, while the compensator's piston cavity is communicated through a filter and a check valve to the oil tank, and the piston cavity is communicated through holes in the cylinder the core and the well is partially filled with a barrier liquid whose density exceeds the density of the borehole fluid reservoir, the check valve is configured to bypass the excess oil from its thermal expansion at 3 ÷ 5 bar.2. The pump unit according to claim 1, characterized in that the drive oil pump is made volumetric, for example gear. The pump unit according to claim 1, characterized in that the distributor is made hydraulically controlled to provide autonomous connection of the hydraulic motor cavities with the input and output of the drive�

Description

The utility model relates to the field of pump engineering, in particular to pumping units designed for lifting liquids from great depths, for example from wells.

A submersible diaphragm electric pump is known, comprising an electric motor kinematically connected to a drive pump plunger installed in an oil-filled housing that is hermetically isolated from the pumped liquid by an elastic diaphragm and compensator, and suction and discharge valves are installed in the electric pump head (see patent RU No. 2062906, C. F 04 B 47/06, 06/27/1996).

A disadvantage of the known design is the low efficiency characteristic of diaphragm electric pumps, and low reliability, due to the frequent failure of the kinematics elements.

Also known is a borehole electro-hydraulic pump unit containing kinematically connected submersible electric motor and a driving oil pump, a working pump with suction and discharge valves, driven by a hydraulic motor, the cylinder cavities of which are connected through the distributor to the inlet and through the safety valve to the output of the drive pump, this rod of the hydraulic motor through the tread is connected to the rod of the working pump, and its body contains front and rear covers, while the unit equipped with an oil tank having a volume compensator, in one of the sections of which there is an overflow valve, a flow regulator and a filter (see, patent RU No. 2166668, class F 04 B 47/08, 05/10/2001)

The disadvantage of this design is the low reliability due to poor sealing of the hydraulic actuator, because volume compensator made in

the form of an elastic diaphragm. A cyclic change in the volume of the diaphragm by 25-50% for each double stroke during operation reduces its resource and leads to a gap. In addition, the gas located in the reservoir fluid diffuses through the walls of the diaphragm into the hydraulic system, which leads to an increase in the volume of the autonomous hydraulic system and rupture of the diaphragm.

The technical problem posed in this utility model is to increase the reliability of the pump unit by preventing depressurization of the oil volume compensator and tread.

This problem is solved due to the fact that the borehole electrohydraulic drive pump unit contains kinematically connected submersible electric motor and a drive oil pump communicated from the inlet side with the oil tank, as well as a working pump with suction and discharge valves, driven by a hydraulic motor, cylinder cavities which are connected through the distributor to the inlet and through the safety valve to the output of the drive oil pump. The hydraulic motor rod through the tread is connected to the working pump rod, and the oil tank is in communication with the oil volume compensator and is made with an oil flow regulator and a filter. The tread is made in the form of at least 2 located concentrically relative to the stem and separated by oil-filled cavities. The oil volume compensator is made in the form of a cylinder in which a piston is installed with the formation of a piston and a piston cavity, while the compensator piston cavity is communicated through a filter and a check valve with an oil tank, and the piston cavity is communicated through holes in the cylinder to the well and partially filled with a barrier fluid, the density of which exceeds the density of the formation fluid of the well. The non-return valve is configured to bypass excess oil from thermal expansion at a pressure of 3-5 bar.

The drive oil pump can be made volumetric, for example gear, and the distributor is made hydraulically controlled to provide autonomous connection of the hydraulic motor cavities with the input and output of the drive oil pump when the working body of the hydraulic motor reaches its extreme positions.

During the analysis of the operation of the borehole electro-hydraulic pumping unit, it was found that the tread and oil volume compensator are the most critical in operation. Oil leakage as a result of depressurization of the tread or as a result of a violation of the integrity of the volume compensator, for example, as a result of a rupture in the elastic shell of the oil volume compensator, can lead to failure of the entire pump unit.

The performance of the tread in the form of at least 2, located concentrically relative to the rod and separated by oil-filled cavities, can dramatically increase the reliability of its operation and almost completely eliminates the release of oil into the well.

The implementation of the oil volume compensator in the form of a cylinder in which a piston is installed with the formation of a piston and a piston cavity, as well as the message of the piston cavity of the compensator through a filter and a check valve with an oil tank, and the communication of the piston cavity through holes in the cylinder with a well when partially filled with barrier fluid, the density of which exceeds the density of the reservoir fluid of the well allows to exclude from the design of the pumping unit elastic materials that form any bands tee. The result is double protection against oil leakage due to the movable piston and the hydraulic piston formed by the barrier fluid. It was found that it is most advisable to adjust the check valve to bypass the excess oil from the tank from its thermal expansion to a pressure of 3 to 5 bar. For the convenience of filling the compensator with barrier fluid and during pumping

of the unit in the transport position, the holes in the compensator cylinder can be blocked, and in the vertical position of the pumping unit, these holes in the compensator cylinder are forcibly communicated with the borehole space with the possibility of entering the reservoir fluid from the borehole. For this, the compensator can be equipped with a plug movable in the axial direction by means of a rotary sleeve with a screw groove, in which a finger is mounted, rigidly connected to the plug.

Figure 1 presents a longitudinal section of a borehole electro-hydraulic pumping unit. Figure 2 presents a section of a compensator for the volume of a borehole electro-hydraulic pump unit. Figure 3 presents a section of the tread of a borehole electro-hydraulic pumping unit.

The borehole electrohydraulic drive unit contains kinematically interconnected submersible motor 1 with hydraulic protection 2 and a drive oil pump 3, as well as a working pump 4 with a suction valve 5 installed in the working body 6 of the pump 4 and the discharge valve 7. The working pump 4 is driven by a hydraulic motor 8. The cavities 9 and 10 of the hydraulic motor 8 are connected through a distributor 11 to the input and output of the drive oil pump 3.

The rod 12 of the hydraulic motor 8 is connected to the working body of the working pump 4 through the tread 13, which is made in the form of at least 2 oil-filled cavities located concentrically relative to the rod 12 and separated by a rod 12 by means of seals 14.

The distributor 11 is made hydraulically controlled to provide autonomous connection of the cavities 9 and 10 of the hydraulic motor 8 when the working body 15 reaches extreme positions with the inlet and outlet of the drive oil pump 3. In addition, the distributor 11 is connected via a pipe 16 to the discharge opening of the oil pump 3 and channel 17,

made in the back cover of the hydraulic motor 8 through the compensator for the volume of oil 18, the oil tank 19 and the pipe 20 with the suction hole of the oil pump.

The volume compensator 18 (Fig. 2) is made in the form of a cylinder 21 with a movable piston 22 interacting with a barrier fluid in the piston cavity 23, communicating through the openings 24 in the sleeve 25 with the space of the well with the possibility of entry into the piston cavity of the reservoir fluid through the openings 24. From the opposite side above the piston in the cylinder 21, a piston cavity is formed, communicated through the holes in the rod with the oil tank 19.

The sleeve 25 is made rotary with a screw groove in contact by means of a finger 26 with a stopper 27.

When turning the sleeve 25, the openings 24 overlap and the piston cavity 23 becomes closed due to the axial movement of the plug 27 and the contact of its outer surface with the seal 28, in order to fill the pump unit with barrier fluid before transportation to the well and back for servicing.

Oil leaks through the rod seals 12 are returned to the system through a pipe 29 connecting the drainage cavity of the hydraulic motor 8 with the oil tank 19. In the tank 19 there is a check valve 30, a flow regulator 31 connected to the rod cavity of the hydraulic motor cylinder, and a filter 32.

The working body 6 of the pump 4 is made in the form of a hollow plunger and is placed in the cylinder 33. In the lower part of the cylinder 33 and the plunger 6 holes 34 and 35 are made for receiving the produced fluid. The discharge valve 7 is installed in the upper part of the cylinder 33.

A downhole electro-hydraulic pump unit is attached to a tubing string 36. A tubing string 36 with a tubing assembly is lowered into a casing installed in the well.

Power supply of the submersible motor is carried out by means of a cable 37, which is attached to the tubing string 36 with clamps.

The discharge pipe 16 passes from the drive oil pump 3 to the distributor 11 and is connected to the safety valve 38 of the tank 19.

Downhole electrohydraulic pump unit operates as follows.

Before immersing the pump unit in the borehole of the cavity of the submersible motor 1, the hydraulic drive system including the drive pump 3, the oil tank 19, the hydraulic motor 8 and other elements, as well as the inner cavity of the tread 13 are filled with purified oil.

The piston cavity 23 of the volume compensator 18 under the piston 22 is filled with a barrier fluid whose density is twice the density of the reservoir fluid.

In the vertical position of the pumping unit at the well, the sleeve 25 is rotated and through the open holes 24, the formation fluid can enter the cavity with the barrier fluid, due to the axial movement of the plug 27.

In this case, the piston 22 makes reciprocating movements in the cylinder 21 when the volume of oil in the hydraulic drive changes for each double stroke of the working body 15 of the hydraulic motor 8, while the piston 22 moves in one direction under the pressure of the oil supplied to the compensator, and in the other direction under the reservoir pressure fluid acting on the barrier fluid.

When the pump unit is immersed in the oil reservoir, the produced fluid enters the cavity of the cylinder 33 and the hollow plunger - the working body 6 of the working pump 4 through the holes 34 and 35 in the lower part of these nodes. Under the influence of hydrostatic pressure, the suction 5 and discharge 7 valves open and the fluid fills the tubing 36 almost to the level of the reservoir.

When you turn on the submersible motor 1, the drive oil pump 3 starts to work, which through the pipe 16 and the distributor 11 supplies oil under pressure to the lower cavity 9 of the hydraulic motor. The working body 15 moves upward, displacing the oil from the upper cavity 9 of the hydraulic motor 8. The oil through the pipe 20 through the distributor 11, the volume compensator 18 tank 19 and the filter 32 is fed to the input of the drive pump.

The difference between the volumetric flow rates of the oil pumped into the hydraulic motor 8 and the oil displaced from it, due to the presence of the rod 12 in the upper cavity, is compensated by changing the oil volume in the compensator 18. This design also provides compensation for changes in the oil volume due to the influence of temperature. Moving the working body of the hydraulic motor up determines the working stroke of the working body 6 of the working pump 4 connected with it. In this case, the produced fluid is injected from the upper cavity of the cylinder 33 into the tubing 36 through the discharge valve 7. At the same time, the lower cavity of this cylinder is filled with fluid flowing from casing string.

When the working body 15 of the hydraulic motor reaches the upper position, the distributor 11 is switched over and the working bodies 15 and 6 of the hydraulic motor 8 and the pump 4 are connected backward by supplying oil to the upper cavity 9 of the hydraulic motor and draining the oil from the lower cavity. When lowering the working body 6 of the pump, the discharge valve 7 closes, and the suction valve 5 opens and passes the produced fluid into the upper cavity of the cylinder of the working pump 4.

When the working body reaches a certain lower position, the distributor 11 moves back and the working cycle described above is repeated.

As a result, an increase in the reliability of the borehole electro-hydraulic pumping unit was achieved by replacing the elastic diaphragms with a compensator with a piston and a barrier fluid, as well as a tread with concentrically located relative to the rod and separated by oil-filled cavities.

This utility model can be used in the oil and other industries, where various fluids are produced from wells.

Claims (3)

1. A borehole electrohydraulic drive pump unit containing a kinematically interconnected submersible motor and a drive oil pump communicated from the inlet side with an oil tank, a working pump with suction and discharge valves, with an actuator driven by a hydraulic motor, the cylinder cavities of which are connected through the distributor to the inlet and through a safety valve - with the output of the drive oil pump, the hydraulic motor rod through the tread is connected to the working pump rod, and the oil tank is connected to oil volume compensator and is made with an oil flow regulator and a filter, characterized in that the tread is made in the form of at least 2 located concentrically relative to the stem and separated by oil-filled cavities, and the oil volume compensator is made in the form of a cylinder, in which a piston is installed with the formation of a piston and a piston cavity, while the compensator's piston cavity is communicated through a filter and a check valve to the oil tank, and the piston cavity is communicated through holes in the cylinder the core and the well is partially filled with a barrier liquid whose density exceeds the density of the borehole fluid reservoir, the check valve is configured to bypass the excess oil from its thermal expansion at 3 ÷ 5 bar. 2. The pump unit according to claim 1, characterized in that the drive oil pump is made volumetric, for example gear. 3. The pump unit according to claim 1, characterized in that the distributor is made hydraulically controlled to provide autonomous connection of the hydraulic motor cavities with the input and output of the drive oil pump when the working body of the hydraulic motor reaches its extreme positions.