UA20359U - Well electro-driven pump unit - Google Patents

Abstract

A well electro-driven pump unit has a working double-acting piston pump with suction and pressure valves, a drive double-acting cylinder, its piston is connected by means of rod to the piston of working piston pump, and oil pump with drive from immersed electric motor. In the housing of the unit oil tank is placed, with compensator of its volume, controlled oil distributor, this has two distribution hydraulic lines through which the piston and the rod working chambers of the drive hydraulic cylinder can be connected to the pumping line of the oil pump and the cavity of the oil tank, and safety valve, this is installed in the pumping line of the oil pump. The oil distributor is arranged as hydraulically controlled distribution oil slide valve with two control cavities, each of those is connected to the cavity of oil tank through throttle. In each of two distribution lines of the slide valve control a hydraulic unit is installed, and hydraulic accumulator connected to it.

Description

Description of the invention

A useful model relates to the field of pump construction, in particular to submersible piston pump units 2 designed to lift reservoir fluid, such as oil, from deep wells that may have a small diameter and a small flow rate.

The well-known volumetric submersible pump with an electric motor | see patent of Ukraine for the invention Mo70397, publ. 15.10.2004 in Bull. Mo10, M. kl.7 E04847/06), which contains a cylinder body, a working chamber, a suction chamber, inlet and outlet devices, a working cylinder, a piston operating in an abrasive medium, 70 which is driven by a unit isolated from the abrasive medium , which transforms the rotary motion of the drive shaft into a rectilinear reciprocating motion of the piston. The unit contains bearings, a drive shaft with rollers and cups with oblique end surfaces fixed on the isolated part of the piston. The glasses are kept from rotating by keyed connections with the body, and the contact of the oblique end surfaces with the rotating rollers is ensured by a guide spring. t Insulation of the cavity in which the drive unit is placed is provided by the piston itself, therefore, with each working stroke of the piston, a vacuum occurs in this cavity, which creates conditions for the penetration of the pumped medium into the cavity of the drive unit. This is a significant drawback of the known device and not only because the ingress of abrasive particles is not desirable for the normal operation of bearing pairs and friction pairs. The constant inflow of the pumped liquid into the cavity of the drive assembly, which has a relatively small volume, and the gradual accumulation of Ti in this cavity will lead to the lagging of the cups from contact with the rollers and the reduction of the stroke of the piston to zero. In addition to this, the high speed of such a submersible pump, 25-50 working strokes per second, in an abrasive environment contributes to the rapid wear of valve inlet and outlet devices.

From the patent of the Russian Federation for the invention |Mo RF 2166668, RO4847/08, publ. 10.05.20011 a well-known submersible electric pump unit containing an oil pump driven by a submersible 29 electric motor, a working piston pump with a piston cylinder, a suction valve located in pistons, a discharge valve and a hydraulic motor for driving a working piston pump, and the cavities of the cylinder of the hydraulic motor are connected through the oil distributor to the inlet and through the safety valve - to the output of the oil pump, and the piston rod of the engine is connected to the piston of the working piston pump through the protector, except moreover, the unit is equipped with an oil tank with a compensator of its volume, in one of the sections of which an overflow valve Ф 30, a flow regulator and a filter are installed, and the hydraulic motor is equipped with a hydraulic brake and limiter of rotation M) of the rod.

In this borehole electric pump unit, the reliability of operation has been improved due to the increased tightness of the hydraulic motor design. However, the performance of this unit is insufficient, which is due to the cyclic supply of pumped liquid by the unit during the "idle" stroke of the piston pump

From unilateral action. high school

The closest analogue in terms of technical essence and achievable results to the claimed useful model is a well electric pump unit according to the patent of the Russian Federation for an invention (Mo

Vy 2235907, M. Kl.": Е04847/06, publ. 10.09.20041. « 20 The well-known well electric pump unit for oil production includes an oil pump with a drive from a gas oil electric motor with a compensator, a working piston pump with a piston cylinder, with a suction the valve is located in the piston, the discharge valve and the hydraulic motor, made as a power 1" double-action hydraulic cylinder for the drive of the working piston pump, and the cavities of the hydraulic motor cylinder are connected through the oil distributor to the inlet and through the safety valve - to the outlet of the oil 45 pump, the unit contains an oil tank with a compensator of its volume, in one of the sections of which are installed

HF overflow valve, flow regulator and filter. In addition, the hydraulic motor is supplied with a mechanical limiter of the piston stroke, which is made as a rod that interacts with a mechanical travel distributor, which provides (in hydraulic switching of the oil distributor, and the working piston pump is supplied with a bypass line, an additional piston cylinder with an additional piston and placed in the latter by an additional 5p Suction spring-loaded valve, while the additional piston is rigidly connected by means of an intermediate rod to the piston of the working piston pump located below it, the cavities of the piston cylinders are separated by the spool of the distributor of the pumping medium, two rows of holes are made in the wall of the distributor for connecting the working pump cavities with a bypass line formed with the help of a shell that covers both piston cylinders from the outside, and the bypass line is provided with a distribution valve located between the rows of holes of the distributor of the pumping medium, and above of the piston cylinder is connected to the discharge valve. c Switching of the oil distributor to ensure the reverse of the hydraulic motor occurs mechanically when the piston of the hydraulic motor reaches its uppermost position or its lowermost position. When using a known downhole electric pump unit for pumping into the formation fluid, for example, oil contaminated with sand and other suspended particles, the mechanical switching system of the oil distributor cannot function reliably because it is tied to specific end positions of the hydraulic motor piston. Sand and other suspended particles can enter and accumulate in the working cavities of the pump cylinder, which leads to a reduction in the stroke of the pump piston and, ultimately, prevents the pump piston from being set to the same position each time, when it is reached, the switch of the oil distributor to the reverse one is ensured a process that leads to the failure of the well electric pump unit and the need to lift it from a deep well, the depth of which can reach 1 km or more, which is expensive, and its subsequent cleaning.

Common essential features of the closest analogue and the claimed device are the following set of them: "Drilling electric pump unit, containing a double-action piston pump with suction and discharge valves, intended for pumping reservoir fluid, a double-action hydraulic cylinder, the piston of which is connected with the help of a rod with a piston of a working piston pump, and an oil pump driven by a submersible electric motor, moreover, the housing of the well electric pump unit contains an oil tank with a compensator of its volume, a controlled oil distributor, which has two distribution hydraulic lines through which the piston and rod working chambers of the drive 7/0 Subcylinder can be connected to the pressure line of the oil pump and to the cavity of the oil tank, and the safety valve, which is installed in the pressure hydraulic line of the oil pump."

The technical problem of the claimed useful model is to increase the duration of operation of the downhole electric pump unit when it is used to pump formation fluid contaminated with suspended particles by using such a hydrofed oil distributor control system, 7/5 Through which the cavities of the drive hydraulic cylinder can be connected to pressure line of the oil pump and with a drain into the cavity of the oil tank, which would allow changing the direction of movement of the drive hydraulic cylinder regardless of the full stroke of the piston of the working piston pump, that is, when the pump piston stops at any part of its stroke, for example, as a result of piston jamming, which allows the pump unit to continue its operation even with an incomplete stroke of the piston of the working piston pump.

The task is achieved with the help of a downhole electric pump unit, which contains a double-action working piston pump with suction and discharge valves, designed for pumping reservoir fluid, a double-acting hydraulic cylinder, the piston of which is connected by a rod to the piston of the working piston pump, and an oil a pump driven by a submersible electric motor, and the housing of the well electric pump unit contains an oil tank with a compensator of its volume, a controllable oil distributor, which has two distribution hydraulic lines, through which the piston and rod working chambers of the drive hydraulic cylinder can be connected to the pressure with the oil line of the pump and with the cavity of the oil tank, and the safety valve, which is installed in the pressure hydraulic line of the oil pump, in which, according to the useful model, the oil distributor is made as a hydraulically controlled oil spool containing two hydraulically controlled cavities, k one of which is connected to the cavity of the oil tank through a throttle, and in each of the two distribution hydraulic lines of the distribution oil spool, a control hydraulic device and a hydraulic accumulator connected to it are installed, and the hydraulic accumulator can be alternately connected through the control hydraulic device with the corresponding distribution hydraulic line from the distribution oil spool and with the corresponding hydro-controlled cavity of the distribution oil spool. at

The proposed implementation of the oil distributor and the presence in each of its two distribution lines of a hydraulic control device with a hydraulic accumulator connected to it, together with other structural features of the well electric pump unit, allow the oil distributor to be controlled non-mechanically only when the piston of the working piston pump reaches its final positions. positions, and hydraulic at any stops of the piston of the working piston pump and the piston of the drive hydraulic cylinder connected to it, which lead to the activation of the safety valve, which in turn leads to the activation of the corresponding control hydraulic device. At the same time, the control hydraulic device switches the hydraulic accumulator connected to it, which was in the "charge" position, to the "discharge" position, connecting its working cavity with the corresponding control cavity of the hydraulically controlled oil spool, as a result of which the latter is hydraulically switched by the hydraulic accumulator to its second position, ensuring the reverse of the drive hydraulic cylinder.

So, the specified implementation of the well electric pump unit provides hydraulic control of the oil distributor, which allows you to change the direction of movement of the drive hydraulic cylinder regardless of the full stroke of the piston of the working piston pump, and therefore allows the pump unit to continue its operation even with an incomplete reduced stroke of the piston of the working piston of the pump, caused by the accumulation in one or two cavities of the working piston pump of a significant number of dirt particles, which prevent the piston of the working pump from making a full stroke, due to which the duration of operation is increased

Ge of a borehole electric pump unit when using it to pump reservoir fluid contaminated with suspended particles.

The control hydraulic devices installed in the two distribution hydraulic lines of the distribution oil Zopotnik can be made similar to each other.

This implementation of control hydraulic devices makes the design of the well electric pump unit more unified.

Each control hydraulic device contains a non-return valve installed in parallel to each other, which is designed to connect the corresponding working chamber of the drive hydraulic cylinder through the distribution valve, an oil spool with drain into the oil tank cavity, a throttle and a functional overflow valve, which is designed to connect the corresponding working chamber of the hydraulic drive cylinder through the distributor oil spool with the pressure line of the oil pump, and which also performs the function of a two-position hydraulic distributor, while the functional overflow valve in its open position ensures the connection of the hydraulic accumulator to the corresponding distributor hydraulic line of the distributor oil spool, and in its closed position 65 ensures the connection of the hydraulic accumulator with the corresponding control cavity of the distribution oil spool.

This implementation of the control hydraulic device provides the simplest and most reliable in operation design of the well electric pump unit, since the functional overflow valve simultaneously performs the functions of two hydraulic devices - the overflow valve and the two-position hydraulic distributor, which is designed to control the operation of the hydraulic accumulator. At the same time, no additional devices are needed to coordinate the operation of two different functional devices, which are embodied in one functional overflow valve.

The control hydraulic device can be made as a single hydraulic unit.

Such a constructive implementation is the most expedient, as it allows, due to the greater compactness of the 7/0, to reduce the dimensions of the control hydraulic device and, in general, the downhole electric pump unit.

The hydraulic accumulator is a piston spring-loaded hydraulic accumulator.

This design of the hydraulic accumulator is the most expedient, since charging and discharging the piston spring-loaded accumulator does not affect the change in the oil volume in the oil tank cavity.

The compensator of the volume of the oil tank is formed by a movable diaphragm, which is installed in the bore of the housing part of the pump unit and separates the cavity of the oil tank from another cavity, which is connected to the radial channel in the housing, which extends to the outer surface of the pump unit.

This execution of the oil tank volume compensator is the most expedient, as it allows you to have a significant reserve volume of oil in the oil tank, taking into account its possible leaks to the outside in the form of an oil film through the sealing gaps, which guarantees the long-term preservation in the oil tank necessary for normal the operation of the well electric pump unit for the amount of oil. This ensures the reliability and duration of operation of the borehole electric pump unit

The rod that connects the pistons of the drive hydraulic cylinder and the working piston pump can be hermetically installed in the longitudinal through hole made in the transverse partition of the housing of the pump unit.

This provides the most structurally simple hermetic separation of the rod cavity of the drive hydraulic cylinder from the rod cavity of the working piston pump.

On the side of the through hole in the transverse partition, an annular groove can be made, which is connected to the radial channel made in the partition, which extends to the outer surface of the pump unit. b zo This design eliminates the possibility of the pumped liquid penetrating through the gaps between the rod and the corresponding hole in the body part into the rod cavity of the drive hydraulic cylinder, in which the oil is located. co

From the side of the through hole in the housing part in the area between the main annular groove and the end surface of this housing part, bordering the rod cavity of the drive hydraulic cylinder, there may be o

Зз5 An additional annular groove is made, which is connected by a channel to the cavity of the oil tank. with

Such an additional groove acts as an oil leakage collecting groove, which prevents oil loss in the event of oil leakage through the gaps between the outer surface of the rod and the inner surface of the housing part hole in which the rod is installed. And therefore, it increases the reliability of the well electric pump unit. "

The applicants do not know the designs of the devices, which contain a set of essential features of the electric pump unit that is being applied for. At the same time, the latter consists of structural elements that can be manufactured by modern pump construction technology. Due to the mentioned advantages of the useful model, the proposed well electric pump unit can find practical application in the production of oil from deep wells with a small flow rate, including those contaminated with sand and other suspended particles. All of the above allows us to conclude that the claimed useful model meets the criteria of "novelty" and "industrial applicability".

In fig. 1 shows a diagram of a well electric pump unit. o In fig. 2 shows the first control hydraulic device installed in one of the two distribution

Ge) lines of the distribution oil spool of the oil pump, and the first hydraulic accumulator connected to it, in the position of charging the accumulator.

In fig. C shows the second control hydraulic device installed in the second distribution line in the distribution oil spool of the oil pump, and the second hydraulic accumulator connected to it, in the position of discharge of the accumulator. c The downhole electric pump unit has a cylinder body 1, which consists of several hermetically connected body parts (in the drawings, the body parts of the cylinder body are conditionally not shown separately). In the bore 2, which is made in the upper part of the housing 1, the piston Z of the working piston pump, intended for pumping formation fluid, is placed, and in the bore 4 - the piston 5 of the drive hydraulic cylinder. The piston Z of the working piston pump and the piston 5 of the drive hydraulic cylinder are connected to each other by means of a common rod 6. The piston Z of the working piston pump divides the bore cavity 2 into the piston working chamber 7 of the working piston pump and the rod working chamber 8 of the working piston pump.

Accordingly, the piston 5 of the drive hydraulic cylinder divides the bore hole 4 into the piston working chamber 9 65 of the drive hydraulic cylinder and into the rod working chamber 10 of the drive hydraulic cylinder.

In the cylinder body 1, inlet channels 11 and 12 are made, in which suction valves are installed,

13 and 14, respectively, as well as outlet channels 15 and 16, in which discharge valves are installed, respectively 17 and 18. Supply channels 11 and 12 with suction valves 13 and 14 installed in them serve to connect the external environment, respectively, with the piston working chamber 7 working piston pump and with rod working chamber 8 working piston pump. Outlet channels 15 and 16 with discharge valves 17 and 18 installed in them serve to connect, respectively, the piston working chamber 7 of the working piston pump and the rod working chamber 8 of the working piston pump with the pressure line 19 of the well electric pump unit.

The downhole electric pump unit contains a submersible sealed electric motor 20, which 70 is mounted outside the cylinder housing 1 on the side of its bottom part and is kinematically connected to the oil pump 21 located in the housing 1. In the lower part of the cylinder housing 1 there is an oil tank 22 with a compensator of its of the volume formed by the diaphragm 23, which is movably installed in the bore 24 of the body. Diaphragm 23 hermetically separates the cavity of the oil tank 22 from the cavity 25 of the housing, which is connected to the radial channel 26 in the housing, which goes to the outer surface of the pump unit.

A safety valve 28 is installed in the pressure line 27 of the oil pump 21. In the lower part of the cylinder housing 1, a hydraulically controlled distribution oil spool 29 is also installed, which contains two control cavities 30 and 31, which are connected to the cavity of the oil tank 22 through throttles 32 and 33, respectively .

The distribution oil spool 29 is designed as two-position and has a position lock 34, which serves to reliably alternately fix the spool in its two working positions! and II. The feed line P of the distribution oil spool 29 is connected to the pressure line 27 of the oil pump 21, and its drain line

T is connected to the oil tank 22. In the initial position, the distribution oil spool 29 can occupy one of its two fixed working positions I or II. In fig. 1, the distribution spool 29 is in position I, fixed by the latch 34, when its distribution line A is connected to the supply line P, and its distribution line B is connected to the drain line T. When the distribution oil spool 29 is in position I, its distribution line A is connected to drain line T and its distribution line B is connected to supply line P.

For supply and removal of oil to/from the working piston chamber 9 of the hydraulic motor and the working rod chamber 10 of the hydraulic motor, channels 35 and 36 are made in the cylinder housing 1, respectively.

Distribution line A of the distribution oil spool 29 is connected to channel 35, and its distribution line

V is connected to channel 36. Gee! similar control hydraulic devices 37 (see fig. 2) and 38 (see fig. 3) are installed in the distribution line A and in the distribution line B of the distribution oil spool 29, each of which is preferably made as a single hydraulic unit. Hydraulic accumulators 39 and 40 are connected to hydraulic control devices 37 and 38, respectively.

The hydraulic accumulator 39 through the control hydraulic device 37 can be alternately connected to the distribution hydraulic line A of the distribution oil spool 29 and with the help of line 41 - to the hydraulic control with cavity Z0 of the distribution oil spool 29. Similarly, the hydraulic accumulator 40 through the control hydraulic device 38 can alternately connect with the distribution hydraulic line B of the distribution oil spool 29 and with the help of line 42 - with the hydraulically controlled cavity 31 of the distribution oil spool 29.

The control hydraulic device 37 contains a non-return valve 43 installed parallel to each other, which is designed to connect the piston working chamber 9 of the drive hydraulic cylinder through the distribution oil spool 29, when it is in position II, with the drain into the cavity of the oil tank 22, throttle 44 and )» functional overflow valve 45, which is designed to connect the piston working chamber 9 of the drive hydraulic cylinder through the distribution oil spool 29, when it is in position I, with the pressure line 2! of the oil pump 22. The functional overflow valve 45 also performs the function of a two-position hydraulic distributor, which in its open position ensures the connection of the hydraulic accumulator 39 with the distribution line A of the distribution oil spool 29, and in its closed position ensures the connection of the hydraulic accumulator 39 with through the control cavity 30 of the distribution oil spool 29 through 2) line 41.

The control hydraulic device 38, which is made similarly to the control hydraulic device 37, contains 1 check valve 46 installed parallel to each other, which is designed to connect the working rod

Ge) chamber 10 of the drive hydraulic cylinder through the distribution oil spool 29, when it is in the position

Y, with a drain into the cavity of the oil tank 22, a throttle 47 and a functional overflow valve 48, which is made similarly to the functional overflow valve 45 and is designed to connect the rod working chamber 10 of the drive hydraulic cylinder through the distribution oil spool 29, when it is in the Я position, with the pressure line 27 of the oil pump 22, and which also performs the function of a two-position hydraulic distributor, while the functional overflow valve 48 as a two-position hydraulic distributor in its open position ensures the connection of the hydraulic accumulator 40 with the distribution line B of the distribution oil spool 29, and in its closed position position ensures the connection of the hydraulic accumulator 40 with the control cavity bo 31 of the distribution oil spool 29 through the line 42.

Structurally, each of the functional overflow valves 45, 48 (see fig. 2 and fig. 3) has a body part 49, in the bore 50 of which a plunger shutter 51 is placed with a spring 52, which acts to close this shutter. Boring 50 has a feed channel 53, a lead ring bore 54 with a lead channel 55 and a control pilot ring bore 56 with a channel 57. The plunger valve 51 on the side of the lead channel 53 has lead 65 radial windows 58, and on its outer cylindrical surface - a control cylindrical groove 59, which is connected to the lead bore 54 through the radial holes 60, 61 and the axial blind hole 62, which are made in the body of the plunger valve 51. The end cavity 63, in which the spring 52 is located, is connected through the holes 62 and 61 and the bore 54 to the lead channel 55 On the outer cylindrical surface of the plunger valve 51, a control cylindrical groove 64 is also made, which is connected to the channel 65 in the body part 49. The inlet channel 53 of the functional overflow valve 45 is connected to line A, and the similar channel 53 of the functional overflow valve 48 is connected with line B. Channel 57 of the functional overflow valve 45 is connected by line 66 to the working chamber of the piston plunger accumulator lyator 39, and a similar channel of the functional 57 overflow valve 48 is connected by line 67 to the working chamber of the piston plunger accumulator 40.

Channel 65 of the functional overflow valve 45 is connected by line 41 to the left control cavity ZO 7/0 of the distribution oil spool 29, and a similar channel of the functional overflow valve 48 is connected to the right control cavity 31 of the distribution oil spool 29 by line 42.

The rod 6, which connects the pistons C and 5, is hermetically installed with the possibility of reciprocating movement in the longitudinal through hole 68 made in the transverse partition 69 of the cylinder body 1 (see Fig. 1). On the side of the through hole 68 in the partition 69, an annular groove 70 is made, which is connected to /5 by a radial channel 71 made in the partition 69, which extends to the outer surface of the housing 1 of the pump unit.

On the side of the through hole 68 in the partition 69 in the area between the annular groove 70 and the end surface of the partition 69 of the housing 1, which borders the rod cavity 10 of the drive hydraulic cylinder, an additional annular groove 72 is made, which is connected by a channel 73 to the cavity of the oil tank 22. Annular groove 70 is a diverting groove, which is designed to prevent the pumped liquid from entering the rod chamber 8 of the working piston pump into the rod chamber 10 of the drive hydraulic cylinder. An additional annular groove 72 is designed to collect possible oil leaks through the gap between the rod 6 and the through hole 68 and return them through the channel 73 to the oil tank 22.

The submersible electric motor 20 is powered by a cable, which is attached with clamps to the column of pump pipes to which the downhole electric pump unit is connected during operation in the well (not shown in the drawing). but

To bring the downhole electric pump unit to working condition, chambers 9 and 10 of hydraulic cylinders, channels 35 and Zb, oil tank 22 and all elements of the hydraulic system connected to tank 22 are filled with oil and sealed from the outside environment. After that, the downhole electric pump unit can be lowered into the casing of the well and immersed in the reservoir fluid. At the same time, the downhole electric pump unit is connected to the surface by a pipeline formed by a column of pump pipes, which is connected to its pressure line 19 and power cable connecting the drive co electric motor 20 with the power source.

The downhole electric pump unit begins to work in a state immersed in the reservoir fluid after turning on the drive electric motor 20. The oil pump 21 s driven by the electric motor 20 sucks oil from the cavity of the oil tank 22 and supplies the entire flow of oil from the cavity 22 through the pressure line 27 to the supply line P distribution oil spool 29.

Before starting work, the distribution oil spool 29 can occupy one of the positions I or I.

Consider the start of operation of a submersible direct-acting piston pump, when the distribution oil spool 29 takes the initial position and, as shown in Fig. 1. When the distributor valve 29.00) is in the | position the flow of oil supplied by the oil pump 21 enters through the pressure line 27, the supply line P, connected to the distribution line A, to the supply channel 53 of the functional overflow valve 45)" of the control hydraulic device 37 and acts on the end of the plunger valve 51. When connecting line A with pressure line 27 of the oil pump, throttle 44 ensures the presence of a pressure difference between channel 53 and cavity 63 and

Channel 55, under the action of which the plunger valve 51 moves to the left (according to the drawing of Fig. 2), compressing the spring 52, and opens the radial windows 58 in the annular bore 54. As a result, the oil flow from line A enters the annular bore 54 and through the outlet channel 55 and channel 35 enters the working piston chamber 9 of the drive hydraulic cylinder, ensuring the driving of the piston 5 of the hydraulic cylinder and the piston 6 of the working piston pump connected to it by a common 2) rod. At the same time, the piston C moves to increase the volume of the rod working chamber 8 of the working piston pump and decrease the volume of the piston working chamber 7 of the pump. As a result, the pressure in the rod working chamber 8 of the working piston pump drops and the reservoir fluid surrounding the outside

The pump aggregate, due to the pressure difference created between it and the cavity of the working chamber 8, enters the latter from the outside through channel 12 and the suction valve 14 opened by the pressure difference, and the air that was in the piston working chamber 7 of the working piston pump through channel 15 and the discharge valve valve 17 is pushed out by the piston from the pump into the pressure line 19 of the pump unit. At the same time, the movement of the piston 5 of the drive hydraulic cylinder leads to a decrease in the volume of the rod chamber 10 of the drive hydraulic cylinder, as a result of which the piston 5 displaces oil from its rod working chamber 10 through the channel 36 and the check valve 46 of the control hydraulic device 38, and further through the lines B and T of the distribution spool 29 for draining into the oil tank 22.

When the piston C reaches its top dead center, it stops and the piston 5 of the sub-cylinder stops with it. This leads to an increase in pressure in the piston working chamber 9 of the hydraulic cylinder, in channel Z5, in lines A and P, in the pressure hydraulic line 27 of the oil pump 21, as well as to the operation of the safety valve 29 and the bypassing of the entire flow of oil from the pressure line 27 of the oil pump 21 into the oil tank 22.

Before the safety valve 29 is activated, the functional overflow valve 45 is in the overflow mode, that is, its spring-loaded plunger valve 51 is kept displaced a certain distance from its closed position 65. When the overflow valve 45 is in the overflow mode, the control annular bore 56 is combined with the annular groove 59, and the channel 57 is connected to the annular bore 54. This allows charging the working chamber of the piston spring accumulator 39 of the control hydraulic device 37 with working oil under the pressure set by the safety valve 28. After activation of the safety valve 28 and charging of the hydraulic accumulator 39, the flow of working oil through the functional overflow valve 45 stops, as a result of which, thanks to the throttle 44 connecting the channel 53 with the channel 55, the pressure difference between the channel 53 and the cavity 63 falls and the plunger valve 51 of the functional overflow valve 45 under the action of the spring 52 moves in the direction of its closure. At the same time, the annular boring 56 is separated from the annular groove 59 and connects with the annular groove 64. As a result, from the working chamber of the charged piston-spring accumulator 39, working oil along the line 66 through channel 57, annular groove 64, channel 65 in the functional 7/0 overflow valve 45 enters the control cavity 30 of the distribution oil spool 29 along the line 41 to the left (according to the drawing in Fig. 1), moves it from the position | to position II and fixes it in this position.

The hydraulic diagram of the distribution line B, which is connected to channel 36, has similar elements to the hydraulic diagram of the distribution line A, which is connected to channel 35. The hydraulic diagram of the distribution line B ensures the operation of the downhole electric pump unit during the return stroke of the piston 5 of the drive hydraulic cylinder.

When fixing the distribution oil spool in position II, its distribution line A is separated from the supply line P and is connected to the drain line T, and its distribution line B is separated from the drain line T and is connected to the supply line P. At the same time, the oil consumption, which is supplied by the oil pump 21, enters through the pressure line 27, the supply line P, connected to the distribution line B, to the supply channel 53 of the functional overflow valve 48 of the control hydraulic device 38 and acts on the end of its plunger 2o valve 51. When connecting the line B with the pressure line 27 of the oil pump, the throttle 47 ensures the presence of a pressure difference between the channel 53 and the cavity 63 and the channel 55 of the functional overflow valve 48, under the action of which its plunger valve 51 moves to the left (according to the drawing of Fig. 3), compressing the spring 52, and opens radial windows 58 into the annular bore 54. As a result, the flow of oil from line B enters the annular bore 54 and further through the outlet ny channel 55 and channel 36 enters the working rod chamber 10 of the drive hydraulic cylinder, ensuring the driving of the piston 5 of the hydraulic cylinder and the piston Z of the pump connected to it by a common rod 6 in the reverse direction. At the same time, the piston C of the pump moves to increase the volume of the piston working chamber 7 of the working piston pump and decrease the volume of the rod working chamber 8 of the working piston pump. As a result, the pressure in the piston working chamber 7 drops, and the reservoir fluid surrounding the pumping unit from the outside, due to the pressure difference between it and the cavity of the working chamber 7, enters the latter from the outside through channel 11 and the suction valve 13, and the reservoir fluid that was in the rod working chamber 8 of the working piston pump through the channel 16 and the discharge valve 18 is pushed out by the piston Z of the pump into the pressure line 19 of the pump unit. At the same time, the movement of the piston 5 of the drive hydraulic cylinder c leads to a decrease in the volume of the piston chamber 9 of the drive hydraulic cylinder, as a result of which the piston 5 displaces oil from its piston working chamber 9 through the channel 35 and the check valve 43 of the control hydraulic device o 37, and further through the lines A and T of the distributor spool 29 for draining into the oil tank 22. p

When the piston C reaches its bottom dead center, it stops and the piston 5 of the hydraulic cylinder stops with it. This leads to an increase in the pressure in the rod working chamber 10 of the hydraulic cylinder, in the Zb channel, in the lines B and R, in the pressure line 27 of the oil pump 21, as well as to the activation of the safety valve 28 and the bypassing of the entire flow of oil from the pressure line 27 of the oil pump in oil tank 22. "

Before the safety valve 28 is activated, the functional overflow valve 48 is in the overflow mode, that is, its plunger valve 51 is kept displaced at a certain distance from its closed position. When the overflow valve 48 is in the overflow mode, its control annular bore 56 is combined with the annular groove 59 of the plunger valve 51, and the channel 57 is connected to the annular bore 54. This allows charging the working chamber of the piston spring accumulator 40 of the control hydraulic device 38 with working oil under pressure settings of the safety valve 28. After the operation of the safety valve 28 and the charging of the hydraulic accumulator 40, the flow of working oil through the functional overflow valve 48 stops, as a result of which, thanks to the throttle 47 connecting the channel 53 with the channel 55, the pressure difference between the channel 53 and the cavity 63 functional overflow valve 48 falls and its plunger valve 51 under the action of spring 2) 52 moves in the direction of its closure. At the same time, the annular boring 56 is separated from the annular groove 59 communicates with the annular groove 64. As a result, from the working chamber of the charged piston spring-loaded accumulator 40, working oil along the line 67 through channel 57, annular groove 64, channel 65 in the functional

Ge) the overflow valve 48 receives along the line 42 to the right (according to the drawing of Fig. 1) the control cavity 31 of the distribution oil spool 29, moves it from position II to position | and fixes it in this position.

After that, the cycles repeat.

Due to the fact that the throttle 44 is installed parallel to the functional overflow valve 45, the required closing speed of the functional overflow valve 45 is achieved when the oil flow stops through the distribution line A. Similarly, the throttle 47 ensures the required closing speed of the functional overflow valve 48 when the pressure in the distribution line B increases. Due to the connection of the control cavities 30, 31 through the chokes 32 and 33 with the drain, the specified speed of movement of the distribution oil spool 29 is ensured when supplying one of these control cavities with the flow of oil from the working chamber of the charged battery 39 or 40, respectively, when the functional overflow valve is triggered 45 on the connection of the charged accumulator 39 with the line 41, or the functional overflow valve 48 on the connection of the charged accumulator 40 with the line 42 is triggered. 65 Since the well electric pump unit is designed to supply to the surface pumped from the depth of the reservoir Therefore, the force that must be applied to the piston of the hydraulic cylinder to move the piston of the working piston pump will be determined by the height of the liquid column (which depends on the depth at which the submersible pump is installed) and its volumetric weight. If the diameters of the pistons of the pump and the hydraulic motor are the same, then the product of the height of the formation fluid column and its volumetric weight will be the working pressure of the oil pump 21. For stable operation of the submersible direct-acting piston pump, the safety valve 28 is set to operate at a pressure value that, depending on the depth of immersion is 10-2595 higher than the working pressure. The pressure that can be created by the oil pump has a technically justified limitation and is indicated by the nominal pressure. When the immersion depth exceeds the nominal pressure of the oil pump, the piston of the working piston pump performs less than the diameter of the piston of the drive hydraulic cylinder. At small submersion depths, for more efficient use of the oil pump capabilities, the diameter of the piston Z of the working piston pump can be made larger than the diameter of the piston 5 of the drive hydraulic cylinder.

During the operation of the pump unit, there is a change in the volume of oil in the oil tank, which is associated with the presence of piston and rod working chambers of the drive hydraulic cylinder, which have different cross-sectional areas. Therefore, in the case of moving the piston 5 towards the rod chamber 10 of the hydraulic cylinder, the volume of oil in the oil tank 22 decreases, and in the case of the reverse movement of the piston 5, the volume of oil in the oil tank 22 increases.

Due to the presence of a movable diaphragm 23, which constantly reacts by moving it to one side or another to pressure drops caused by a change in the volume of oil in the oil tank 22, the internal volume of the oil tank 22 always corresponds to the volume of oil in it. The movable diaphragm 23 maintains the pressure level of the working fluid in the cavity of the oil tank 22 at the level of the formation fluid pressure in the external environment. This allows you to avoid the creation of rarefaction or excessively high pressure in the oil tank 22, which is necessary for the reliable operation of the oil pump 21.

Claims (9)

Formula of the invention - 1. Downhole electric pump unit, containing a double-acting piston pump with suction and discharge valves, intended for pumping reservoir fluid, a double-acting hydraulic cylinder, the piston of which is connected by a rod to the piston of the working piston pump, and an oil pump - with a drive from a submersible electric motor, and the housing of the well electric pump unit contains an oil tank with a compensator of its volume, a controlled it) oil distributor, which has two distribution hydraulic lines, through which the piston and rod working chambers of the drive hydraulic cylinder can be connected with the pressure line of the oil pump and with the cavity of the oil tank, and the safety valve, which is installed in the pressure hydraulic line of the oil pump, which is characterized by the fact that (2 35 the oil distributor is made as a hydraulically controlled distribution oil spool containing two control c cavities, each of which are combined with poro through the throttle, and in each of the two distribution hydraulic lines of the distribution oil spool, a control hydraulic device and a hydraulic accumulator connected to it are installed, and the hydraulic accumulator can be alternately connected through the control hydraulic device to the corresponding distribution hydraulic line of the distribution oil spool and with " by the corresponding control cavity of the distribution oil spool. what! c 2. Well electric pump unit according to claim 1, which is characterized by the fact that the control hydraulic devices installed in two distribution hydraulic lines of the distribution oil spool are made 1" similar to each other. 3. Downhole electric pump unit according to claims 1 or 2, which is characterized by the fact that each control hydraulic device contains a non-return valve installed in parallel with each other, which d) is designed to connect the corresponding working chamber of the drive hydraulic cylinder through the distribution oil spool with drain in the cavity of the oil tank, the throttle and the functional overflow valve, which is designed to connect the corresponding working chamber of the drive hydraulic cylinder through the distribution oil spool with the pressure line of the oil pump, and which also performs the function of a two-position hydraulic distributor, while the functional overflow valve in its in the open position, it provides the connection of the hydraulic 1 accumulator with the corresponding distribution hydraulic line of the distribution oil spool, and in its closed position, it provides the connection of the hydraulic accumulator with the corresponding control cavity of the distribution oil spool. 4. Downhole electric pump unit according to any of items 1-3, which is characterized by the fact that each control hydraulic device is made as a single hydraulic unit. 5. Downhole electric pump unit according to any of items 1-4, characterized in that the hydraulic accumulator is a piston spring-loaded hydraulic accumulator. 6. Downhole electric pump unit according to any of items 1-5, which is characterized by the fact that the compensator of the volume of the oil tank is formed by a movable diaphragm, which is installed in the bore of the body of the pump unit and separates the cavity of the oil tank from another cavity, which is connected with a radial channel in the housing that extends to the outer surface of the pump unit. 7. Downhole electric pump unit according to claim 1, which is characterized by the fact that the rod that connects the pistons of the drive hydraulic cylinder and the working piston pump is hermetically installed in the longitudinal through hole made in the transverse partition of the pump unit housing. 65 8. Downhole electric pump unit according to claim 7, which is characterized by the fact that an annular groove is made on the side of the through hole in the transverse partition, which is connected to the radial channel made in the partition, which extends to the outer surface of the pump unit. 9. Downhole electric pump unit according to claim 8, which is characterized by the fact that on the side of the through hole in the transverse partition in the area between the main annular groove and the end surface of the transverse partition bordering the rod cavity of the drive hydraulic cylinder, an additional annular groove is made, which is connected by a channel with the oil tank cavity. what from (o) iv) (ze) "c) s - i" ime) ("c) (95) 1 3e) 60 b5