WO2019108160A1 - Linear electrical submersible pump assembly - Google Patents

Abstract

The invention relates to the field of petroleum extraction, in particular to assemblies comprising displacement pumps powered by submerged linear electric motors, and can be used to extract formation fluids from low-yield wells from great depths. The described technical solution provides standardization of design with improved ease of manufacture owing to the production thereof from detachable, interchangeable modules. The described implementation helps to reduce the dimensions of the pump assembly. Implementation of a telemetry system, according to a described embodiment of the invention, provides an increased level of protection from high-voltage interference and high voltage by means of an insulation testing mode carried out by hardware and software of an above-ground unit of the telemetry system. In addition, the implementation of said design helps to reduce dynamic loads on structural elements of an electric motor, and also extends the service life thereof.

Description

 Linear electric submersible pumping unit The invention relates to the oil industry, in particular, to installations with volumetric pumps driven by submersible linear electric motors, and can be used to extract reservoir fluids from a limited flow of wells from large depths.

In the proposed device for driving the plungers of the pump uses a linear submersible valve motor LPVED. Known LPVED contain inductors, forming a fixed part of the stator, and the movable part of the slide, formed by permanent magnets located in the bore of the stator. The specified slider is connected to the pump plungers and provides for the transmission of reciprocating motion. Changing the polarity of the voltage in the stator winding, ensures the forward movement of the slider in the longitudinal direction. This type of equipment has found wide application, mainly in small diameter wells with a low flow rate of less than 25 m / day, and as the number of such wells increases every year, such installations are becoming more and more popular. For these reasons, increasingly high requirements for manufacturability, maintainability and reliability of submersible pumping units.

 Most of the currently known operating pumping installations include a plunger pumping unit of reciprocating action and connected to it, by means of a threaded connection, a submersible linear electric motor with telemetry units enclosed in a single housing, as well as a hydroprotection unit.

 From the application for the invention US2015 / 0176574A1, F04B 47/00 06/25/2015, a device is known that comprises a submersible borehole pump consisting of a stationary cylinder and a movable plunger, as well as a submersible motor connected to the borehole pump, by means of a threaded or flange connection. The specified engine connected to the plunger of a submersible borehole pump, and configured to form a reciprocating movement of the plunger.

 The disadvantage of this technical solution is the relatively low reliability associated with the absence of telemetry units and a hydraulic compensator.

From the patent for invention RU2549381 dated 04.27.2015, IPC F04B 47/06; F04B 17/03 known linear motor, submersible pumping installation which contains a sealed stator with cores installed in it with coils, current lead and head for connection to the pump. In the stator there is a movable rod with a connecting rod for connection with the pump plunger and an active hermetic slider connected to the rod by means of a coupling. The slider contains permanently mounted permanent magnets. The head is connected to the stator housing by a threaded connection through spacers with sealing elements. To the base of the stator, similar to the method attached an elastic diaphragm compensator, which is made in the form of a bubble, having a diameter in the middle part greater than the diameter of each end part, with one end of the diaphragm connected to the stator base, and its other end connected to the coupling connecting the electric motor to the compensator.

 The disadvantages of the described technical solution include the absence of a telemetry unit and control elements of the motor, which can lead to its inefficient operation.

Also, from the patent for invention RU2615775 from April 1, 2017, IPC F04B 47/06; F04B 17/03, well pumping unit installed in the wellbore, containing a submersible part, comprising a plunger pump placed in a single housing, equipped with pressure valves, and a gravity gas separator, above which a check valve block is placed, containing a connecting sleeve for mounting a well pumping unit to the tubing string, as well as a submersible linear electric motor installed under the plunger pump, including a stationary part in the form of a stat ora with three-phase winding and installed temperature sensors, and a movable part located in the stator bore in the form of a slider, made with the possibility of reciprocating motion relative to the stator. A telemetry unit is placed under the linear motor, including pressure and temperature sensors of the well fluid, a vibration sensor, an inclinometer and a measuring unit connected to temperature sensors installed in the linear motor and connected to the ground control unit via a zero star windings of the linear motor. The design described above is a working model of a submersible pumping unit, which is currently in operation, the shortcomings of the described technical solution include the implementation of the design in a single package, which can complicate its operation and reduce manufacturability, as well as maintainability.

 The specified technical solution is taken as the nearest equivalent.

The technical problem to which the invention is directed is the creation of a linear electro-immersion pumping unit with high performance, increased reliability and maintainability, as well as made with the possibility of operation in wells of different diameters and productivity.

 The technical result achieved from the implementation of the claimed technical solution is to unify the design, reduce its size, as well as improve the manufacturability, which allows to manufacture individual modules of the pump unit regardless of the completion of the assembly stages and lead to significant savings in working time with increasing production volumes . Also, the modularity of the design significantly increases its performance, in particular, maintainability, allowing you to replace the faulty module and resume operation of the pumping unit as soon as possible.

The essence of the claimed invention lies in the fact that the linear electro-submersible pumping unit is made in the form of modules enclosed in separate enclosures connected to each other by means of a detachable connection with the formation of a single oil-filled system. This installation includes a linear motor module connected by a cable line to a ground control unit, by sealed plug connection. The plug-in connection is made outside the current lead head on an elongated conductor. At the base of the electric motor, a hydraulic compensator module is installed, which includes an elastic diaphragm, the internal cavity of which is in fluid communication with the stator cavity of the linear electric motor by means of a connecting channel passing through the attachment points of the elastic diaphragm. The specified channel is part of the oil line of the refueling of the linear electro-immersion pumping installation, in the cavity of which, wires of communication with the ground control unit are laid. Wires are connected to the submersible module of the telemetry system with implemented hardware-software isolation testing mode by the ground control unit. In this case, the hydrocompensator module contains a hydromechanical damper of the lower extreme point of the moving part of the linear actuator, which is an element of the damping system, which also contains the damper of the upper extreme point placed in a separate housing and installed between the linear motor module and the pump unit.

According to a preferred embodiment of the invention, the linear electrophorean pumping unit, a plug-in connection of modules, is made according to the principle of a flange connection, consisting of threaded bushings mounted at the ends of the abutting modules. In this case, one of the sleeves contains a flange, and the second is the counterpart, with pre-installed studs. The telemetry module is equipped with a set of interchangeable flanges with mounting holes located depending on the case diameter of the electric submersible pump unit, the diameter of the mounting hole of the flange being constant and corresponding to the diameter of the unit case. According to another preferred embodiment of the invention, the module of the telemetry system comprises a filtering-switching device including a low-pass filter with a switching element of the control system and is connected to a ground control unit containing a low-pass filter installed on the communication line with the secondary winding of a three-phase transformer and made with the ability to protect the system from high voltage. Also, the ground unit contains a switching device, made with the possibility of changing the polarity of the voltage supplied to the line for measuring the insulation resistance, associated with a voltage-relief resistor proportional to the current of the communication line.

 According to a preferred embodiment of the invention, the elastic diaphragm of the hydraulic compensator module, at the attachment points, is hermetically fixed by means of a composite collar and protected from mechanical damage by means of a non-metallic insert designed to limit the deformations of the elastic diaphragm. In this case, the elastic diaphragm of the module of the hydraulic compensator can be placed eccentrically with respect to the axis of symmetry of the linear electric submersible pumping unit.

According to a preferred embodiment of the proposed technical solution, the plug connection is made in the dimension of the pumping unit housing, defined by its largest cross section and includes the plug socket, which is outside the current lead head, on the extended conductor. The receptacle consists of a sealed enclosure with an inwardly fixed and fixed by means of sealing polymer elements, at least one conductive core, the free end of an elongated conductor installed in the current lead head with two-sided sealing, b by crimping deformable elements. Also according to the specified embodiment, the hermetic plug-in connection is implemented within the platform, recessed relative to the surface of the transition coupling, installed between the outlet of the pumping unit and the inlet of the tubing.

 The essence of the claimed invention lies in the fact that the damping system includes at least one hydromechanical device for compensating the dynamic load, installed in at least one of the extreme points of travel of the moving part of the linear actuator. The specified device consists of a cylindrical cavity filled with working fluid with overflow openings, as well as a movable hollow piston and a counter supporting element, with an elastic element installed between them. Moreover, the specified cylindrical cavity, made with the possibility of filling the working fluid from the environment of the pumping unit.

 In the specified damping system, the bypass holes of the hydromechanical device are spaced along the length of its cylindrical cavity and are made with the possibility of slowing down the stroke of the piston, as they alternately overlap the body of the piston and increase the resistance to outflow of the working fluid.

 Also, according to a preferred embodiment of the damping system, the hydromechanical device installed at at least one of the extreme points of travel of the movable part of the linear submersible electric motor is configured to provide communication indicated by the movable part with the plunger of the pump unit by means of a connecting element installed in the piston cavity.

The specified movable part of the linear submersible electric motor is connected to the plunger of the pump unit by means of a connecting link, consisting of a friction pair formed by a hollow body element with a movable rod inside. The diameter of the movable rod is equal to the diameter of the movable part of the linear submersible electric motor, while the longitudinal dimensions and stroke of the movable rod are selected so as to ensure at least partial positioning of the movable part of the linear submersible electric motor in the cavity of the housing element of the friction pair. Compensating thereby the radial loads on the moving part of the linear electric motor, ensuring centering and sealing of the specified moving part.

 According to the described implementation variant, the movable part of a linear submersible electric motor consists of a set of permanent magnets, separated by ferromagnetic inserts - magnetic field concentrators, between which copper alloy bushes are installed over permanent magnets. These sleeves reduce the friction coefficient by transferring a part of the material to the inner surface of the guide tube as they wear out. At the same time, the guide tube forms with the moving part of the linear electric motor a friction pair with a reduced friction coefficient. Also, according to the proposed embodiment, the hardness of the guide tube is higher than the hardness of ferromagnetic inserts and copper alloy bushings. The specified guide tube is made of a non-magnetic material, while its necessary hardness is achieved by surface hardening.

 The essence of the proposed technical solution is explained, but not limited to the following graphic materials:

Fig.1 - linear electrophoreses pumping unit general view;

figure 2 - submersible part of the pumping unit;

fig.Z - module of the hydraulic compensator;

4 is a block diagram of a measuring telemetry system; 5 is a hydromechanical damper of the lower extreme point;

6 - hydromechanical damper upper extreme point;

Fig.7 - flange connection modules electrophore pumping unit;

Fig.8 is a variant of flange connection of the submersible module of the telemetry system with the pumping unit case;

Fig.9 - "View-A" flange connection of the submersible module of the telemetry system;

figure 10 - cable connections linear electrophoreses pumping unit;

11 - plug socket in the section;

Fig - head current lead in section;

Fig - connecting link of the moving part of a linear submersible electric motor;

Fig.14 - structural elements of the module linear motor in the section.

 The inventive linear submersible pump installation, contains ground 1 (figure 1) and submersible 2 parts. The ground part is represented as a ground control unit 3, made in the form of a three-phase high-frequency inverter-regulator and an output transformer connected to a linear submersible motor 4 by a cable line 5, through a sealed plug connection 6, which is outside the current lead head on the elongated conductor 7.

The load part 2 (Fig. 1, 2) is formed from a linear valve motor 4, a hydrocompensator 8, a damping system 9 connected to the pumping unit 10 and the immersion module of the telemetry system 11. In the preferred embodiment, the pumping unit presented in the form of a double-action plunger pump with built-in filters and a gravitational gas separation zone.

 The immersion module 11 of the telemetry system is installed in the lower part of the pumping unit, includes a set of sensors measuring the parameters of the well and the motor connected to the ground control unit through the zero point of the windings of the linear motor connected by a star.

 These components are made in the form of modules enclosed in separate enclosures connected to each other through a detachable connection with the formation of a single oil-filled system.

The module of the hydraulic compensator 8 (FIG. 3) is installed at the base of the electric motor, includes an elastic diaphragm 12 with the guide tube 13 placed inside, the movable part of the linear electric motor. The elastic diaphragm 12 at the points of attachment is hermetically sealed by means of the composite collar 14 and protected from mechanical damage by means of non-metallic inserts 15 made with the possibility of limiting its deformations. Also, the elastic diaphragm of the hydraulic compensator module can be placed eccentrically with respect to the axis of symmetry of the linear electro-immersion pumping unit. The internal cavity of the specified diaphragm is in fluid communication with the cavity of the stator 16 of the linear motor 4 through the connecting channel 17, passing in the attachment points of the elastic diaphragm. The specified channel is part of the oil line 18 refueling linear electric submersible pumping unit. In the cavity of the highway, laid the wire 19 connection with the ground control unit. Wires are connected to a submersible module 1 1, a telemetry system or other electrical equipment installed in the lower part of a linear electric motor. In the telemetry system used (figure 4), a hardware-software isolation test mode is implemented by the ground control unit. The immersion module of the telemetry system contains a set of measuring sensors 20, a voltage stabilizer 21, a resistor 22, an information acquisition and transmission device 23, an electronic controlled switch 24 connected to the motor windings through a resistor 25 and a filtering and switching device 26 including a low-pass filter with a switching element management system. The immersion telemetry module is connected to a ground control unit 3 containing a low-pass filter 27, which is installed on the communication line with the secondary winding of a three-phase transformer 28 and configured to protect the system from high voltage. Also, the ground unit contains the power source 29, the device 30 receiving and processing information. The ground unit also contains a switching device 31, made with the possibility of changing the polarity of the voltage supplied to the line for measuring the insulation resistance, associated with the resistor 32 of the voltage proportional to the current of the communication line.

 The damping system is integrated into the design of the pumping unit, whereby it is possible to ensure its reliable and uninterrupted operation. The hydrocompensator module 8 contains a hydromechanical damper 33 (FIG. 3) of the lower extreme point of the stroke of the moving part of the linear actuator, which is shown in detail in (FIG. 5).

The specified hydromechanical damper is part of the damping system, which also contains a damper 34 (6) upper extreme point, placed in a separate case and installed between the module of the linear motor 4 and the pumping unit 10 (figure 2). The hydromechanical devices used in the construction of the damping system contain a cylindrical container 35, 351 filled with working fluid with bypass openings 36, 36 _b as well as a movable hollow piston 37, 37 _] with a counter supporting element 38, 38c and an elastic element 39 installed between them. cylindrical cavity 35, 35 is made with the possibility of filling the working fluid from the environment of the pumping unit.

The bypass holes 36, 36 _] hydromechanical device spaced along the length of its cylindrical cavity 35, 35 _j and made with the possibility of slowing down the stroke of the piston 37, 37 _] , as they alternately overlap the body of the piston and increase the resistance to outflow of the working fluid. Also according to a preferred embodiment of the damping system, a hydromechanical device installed at at least one of the extreme points of travel of the moving part of the linear submersible electric motor, in particular the uppermost point made with the possibility of providing the connection specified by the moving part with the plunger of the pump unit 10, by means of a connecting element installed in the piston cavity. The cavity of the piston 37 _] and the counter supporting element 38 _{] are} associated with the formation of a cavity in which the connecting element of the movable part of the linear electric motor 4 is installed with the plunger of the pump unit 10. An additional restraining force is created by the elastic element 39, which also serves as the return mechanism of the piston 37, 37 _] . Re-filling the cylindrical cavity 35, 35 _] , hydromechanical device occurs during the reverse translational movement of the piston through the bypass holes 36, 36 _] .

Also according to the described embodiment of the invention, a guide tube 13 of the movable part is installed in the cavity of the piston 37 linear motor. During the course of the movable part down to the lower extreme point, a column of fluid located in the cavity of the guide tube 13 installed in the cavity of the piston 37 is discharged through the holes 40 in the lower part of the indicated guide pipe, while the cavity of the piston 37 narrows in relation to the diameter the guide tube 13, pre-slows down the moving part, before contact with the said piston 37.

 The described modules of the pumping unit are connected by means of a detachable connection, made on the principle of a flange connection (FIG. 7), consisting of interfaced modules installed at the ends, threaded bushings 42, 43. At the same time, one of the bushings 42 contains a flange 44, and the second 44 is the counterpart with pre-studs 45. It should also be noted that the module of the telemetry system is made with the ability to install various interchangeable flanges 46 (Fig.8) with mounting holes 47 (Fig.9), located depending on the diameter of the body el The submersible pump installation, the diameter of the mounting hole 48 of the flange, is made constant and corresponds to the diameter of the housing 49 of the module of the telemetry system.

As mentioned earlier, the connection of the ground 1 and submersible 2 parts of the pump unit is provided by means of a cable line 5 with a plug connection 6. The specified connection is made in the dimension of the pump unit housing, defined by its largest cross section. The plug connection (FIG. 10) contains, outside the current lead head 50 (shown in detail in FIG. 12) of the electric motor 4, a plug socket 51 (FIG. 1-1) on the extended conductor 7. The receptacle consists of a sealed enclosure 52 with at least one conducting core fixed inside and fixed by means of sealing polymeric elements 53 54. The free end of the elongated conductor is installed in the head of the current lead 50 (Fig. 12) with double-sided sealing, by means of a crimping deformable element 55 with crimping nuts 56.57 with gland rings 58. Also according to the specified embodiment, a sealed plug connection is arranged within pad 59, recessed relative to the surface of the transitional coupling 60 (figure 10), installed between the output of the pump unit and the inlet of the tubing string 61 (figure 1).

 The movable part 62 (Fig. 13) of the linear submersible electric motor 4 is connected to the plunger 10 of the pump unit by means of a connecting link 63 consisting of a friction pair formed by a hollow body element 64 with a movable rod 65 inside, the diameter of which is equal to the diameter of the movable part 62 of the linear submersible electric motor, in this case, the longitudinal dimensions and stroke of the movable rod 65, are chosen in such a way that would ensure at least partial positioning of the movable part 62 of the linear submersible electric motor 4 into the cavity body member 64 of the friction pair. The specified pair of friction perform sufficiently necessary precision machining of contact surfaces. This embodiment allows you to create a labyrinth seal area, and to ensure the centering of the moving part of the electric motor with the compensation of radial loads, as well as protection from ingress of mechanical impurities into the cavity of the guide tube of the moving part of the linear actuator.

According to the described embodiment of the invention, the movable part 62 (FIG. 14) of the linear submersible electric motor 4 consists of a plurality of permanent magnets 66, separated by ferromagnetic inserts - magnetic field concentrators 67, between which copper alloy sleeves 68 are installed over the permanent magnets. As well as an embodiment of the sleeve 68 may be made of a polymeric material. These bushings protect permanent magnets from mechanical damage, as well as reducing the friction coefficient, by transferring a part of the material to the inner surface of the guide tube 13, as they wear out. In this case, the guide tube forms with the movable part 62 of the linear submersible electric motor 4 a friction pair with a reduced friction coefficient. Also according to the proposed embodiment, the hardness of the guide tube 13 is higher than the hardness of the ferromagnetic inserts 67 and the copper alloy bushings 68. Said guide tube 13 is made of a non-magnetic material, while its necessary hardness is achieved by surface hardening.

 The implementation of the described technical solution contributes to the achievement of the technical result, ensuring the unification of the design with improved manufacturability, through its implementation of easily removable interchangeable modules. Also described the implementation of the cable plug connection and the module of the hydraulic compensator helps to reduce the size of the pump unit.

 The implementation of the telemetry system, according to the claimed invention, provides an increase in the level of protection against high-voltage interference by installing filtering devices in the surface and immersion units, moreover, the application of the described technical solution allows to increase the reliability of operation by providing protection against high voltage and hardware-software implementation isolation test mode ground block.

The device described damping system integrated into the design of a submersible pumping unit without a significant increase in its dimensions, and the implementation of the movable part of a linear actuator with elements that reduce the coefficient of friction, reduces the dynamic loads on the structural elements of the electric motor, and also increases its service life.

Claims

Claims Linear electric submersible pumping unit 1. Linear electric submersible pumping unit associated with a ground control unit including a linear submersible electric motor with a hydrocompensator and a damping system, as well as the associated pump unit with built-in filters and a gravitational gas separation zone, a telemetric system that includes a set of sensors measuring well parameters and an electric motor associated with the ground control unit through the zero point of the windings of a linear electric motor connected by a star, while the ground control unit The device is made in the form of a three-phase high-frequency inverter-regulator and an output transformer connected to a submersible linear electric motor via an insulated three-wire cable, characterized in that it is made in the form of modules enclosed in separate housings connected to each other through a detachable connection to form a single oil-filled system, including a linear motor module connected by a cable line to the ground control unit, by means of a sealed plug Connections outside the current lead head on the elongated conductor, a hydro-compensator module is installed at the base of the electric motor, including an elastic diaphragm, the internal cavity of which is in fluid communication with the stator cavity of the linear electric motor through a connecting channel passing through the points of attachment of the elastic diaphragm, and this channel is a part of the oil line of the refueling of the linear electro-submersible pumping installation, in the cavity of which the connection wires with the ground one are installed Locke control connected to the submersible unit telemetry system implemented by hardware and software verification regime isolation ground control unit, while the hydraulic compensator module contains a hydromechanical damper of the lower extreme point of the moving part of the linear actuator, which is an element of the damping system, which also contains the upper extreme point damper installed between the linear motor module and the pump unit.  2. Linear electric submersible pumping installation according to claim 1 is different in that the plug-in connection of modules is made according to the principle of a flange connection consisting of spliced modules installed at the ends of the butted modules, threaded bushings, and the second is the counterpart, with preset studs, however, the module of the telemetry system is equipped with a set of interchangeable flanges with mounting holes located depending on the diameter of the casing of the electric submersible pumping unit, with the diameter of anovochnogo opening flange formed constant and corresponds to the diameter of the module housing. 3. Linear electric submersible pump installation according to claim 1, characterized in that the module of the telemetry system contains a filtering switching device including a low-pass filter with a switching element of the control system and is connected to a ground control unit containing a low-pass filter installed on the communication line with the secondary winding of a three-phase transformer and configured to protect the system from high voltage, as well as a switching device configured to change the polarity of voltage supplied to the line for measuring the insulation resistance associated with a voltage release resistor proportional to the current of the communication line. 4. Linear electric submersible pumping unit according to PL is characterized in that the elastic diaphragm of the hydrocompensator module, at the attachment points, is tightly fixed by means of a composite clamp and protected from mechanical damage, by means of a non-metallic insert, made with the possibility of limiting the deformations of the elastic diaphragm. 5. Linear submersible pump installation in PP.1; 3 differs in that the elastic diaphragm of the module of the hydrocompensator is placed eccentrically with respect to the axis of symmetry of the linear electro-submersible pumping unit.  6. Linear electric submersible pumping installation according to claim 1 is characterized in that the plug connection is made in the envelope of the pumping unit housing, defined by its largest cross section and includes, outside the current lead head, on the extended conductor, the plug socket consisting of a sealed case and fixed by means of sealing polymer elements, at least one conductive core, with the free end of an elongated conductor installed in the head current and two-way seal by crimping the deformable elements.  7. Linear electric submersible pump unit according to claims 1; 5 differs in that the hermetic plug connection is implemented within the site, recessed relative to the surface of the transition coupling, installed between the outlet of the pump unit and the inlet of the tubing. 8. Linear electric submersible pumping unit associated with a ground control unit, including a linear submersible electric motor with a hydraulic compensator and a damping system, as well as the associated pump unit with built-in filters and a gravitational zone gas separation, and a telemetry system, which includes a set of sensors measuring the parameters of a well and an electric motor connected to a ground control unit through the zero point of the windings of a linear electric motor connected by a star, while the ground control unit is designed as a three-phase high-frequency inverter-regulator and an output transformer connected to submersible linear motor through an insulated three-wire cable, characterized in that the damping system includes at least At least one hydromechanical device for dynamic load compensation, installed in at least one of the extreme points of travel of the moving part of the linear actuator, which consists of a cylindrical container filled with working fluid with overflow holes, as well as a movable hollow piston and a counterpart element, c installed between them by an elastic element, and the specified cylindrical cavity made with the possibility of filling the working fluid from the environment of the pumping unit.  9. Linear electric submersible pump installation of claim 8 is characterized in that in the damping system, the bypass holes of the hydromechanical device are spaced apart along the length of its cylindrical capacity and are made with the possibility of slowing down the piston stroke as the piston body alternates and the resistance to outflow of the working fluid increases. 10. Linear electric submersible pumping installation of claim 8 is characterized in that the hydromechanical device installed in at least one of the extreme points of travel of the moving part of the linear submersible electric motor is configured to provide the connection specified by the movable part with the plunger of the pumping unit by means of connecting element installed in the cavity of the piston. 11. Linear electric submersible pumping installation is characterized in that the movable part of the linear submersible electric motor is connected to the plunger of the pump unit by means of a connecting link consisting of a friction pair formed by a hollow body element with a movable rod inside, the diameter of which is equal to the diameter of the movable part of the linear submersible electric motor, while the longitudinal dimensions and stroke of the movable rod, are chosen in such a way that to ensure at least partial positioning of the movable part linear submersible electric motor in the cavity of the body element of a friction pair. 12. Linear electric submersible pump installation according to claim 1; 8; 11 is distinguished by the fact that the movable part of a linear submersible electric motor consists of a set of permanent magnets separated by ferromagnetic inserts — magnetic field concentrators, between which copper alloy bushes are installed over the permanent magnets.  13. Linear submersible pump installation according to claim 12 is characterized in that the guide tube forms with the moving part of a linear electric motor a friction pair with a reduced friction coefficient, while the hardness of the guide tube is higher than the hardness of ferromagnetic inserts and copper alloy bushings.  14. Linear submersible pump installation in paragraph 12 is characterized in that the guide tube is made of non-magnetic material, while its necessary hardness is achieved by surface hardening.