RU55866U1 - COMPOSITION CASE OF SUBMERSIBLE CENTRIFUGAL PUMP INSTALLATION AND COUPLING FOR CONNECTION OF CASING SECTIONS - Google Patents

Abstract

Technical solutions relate to hydraulic engineering, as well as to methods for intensifying oil production, and can be used in the oil industry to create submersible centrifugal pump units equipped with sectional submersible electric motors. The technical result achieved during the implementation of the first technical solution is to simplify the process of assembling the casing during installation of the pump unit in the well. The technical result achieved by the implementation of the second technical solution is to expand the scope of application of composite housings and reduce the drop in efficiency of the pump unit equipped with a composite housing, by ensuring that the passage section is sufficient for normal fluid flow in the coupling location zone to connect the housing sections without significantly reducing the mechanical coupling strength, including for limited diametrical dimensions of the casing and coupling. The composite casing of a submersible centrifugal pump installation includes a hollow cylindrical body made with the possibility of placing an electric motor of a submersible centrifugal pump installation inside it. The housing of the casing consists of at least two cylindrical sections, made with the possibility of connection using a sleeve, which includes a cylindrical sleeve, one end of which is made with a landing section to accommodate the end of the section of the housing with coverage of the landing section of the coupling. Through radial holes are made on the said end part of the section, and radial holes are made on the coupling seating section with the possibility of coaxial arrangement with the holes of the section and with the possibility of placing embedded elements in said holes for fixing the coupling relative to the section in the axial direction. The coupling for connecting the sections of the casing of the submersible centrifugal pump installation includes a cylindrical sleeve, one end of which is made with a landing section such to be placed in the cavity of the section of the casing and fixing the coupling. On the inner surface of the sleeve there are made axially oriented grooves open at both ends for the passage of the pumped liquid, and at least part of the length of the fitting section of the coupling grooves are made through.

Description

Technical solutions relate to hydraulic engineering, as well as to methods for intensifying the production of oil, water and other soluble or fusible substances or minerals from boreholes and can be used in the oil industry to create submersible centrifugal pumping units suitable for use below the interval of perforation of the well, and also in wells with a high gas factor and a high content of solids in the reservoir fluid, mainly pumping units equipped with section wells rusnyh electric motors.

Increasing the depth of the pump descent allows you to stabilize the work of a submersible centrifugal pump and increase well productivity at low bottomhole pressure, as well as increase the pressure at the pump inlet and, accordingly, reduce the amount of free gas in the reservoir fluid. The main problem that arises when the submersible pump unit is lowered below the well perforation interval is the need to ensure sufficient cooling of the submersible electric motor (SEM). To solve this problem, including special

the casings are fixed above the pump inlet, while the flow of the pumped fluid moves from the perforation interval to the pump intake through the lower end of the casing located below the SEM, ensuring its cooling.

In addition, similar casings can be used to increase the stability of the unit when operating wells with a high gas factor, to install a downhole filter, a liner for cleaning the sump, etc. (in these cases, the unit can be placed above the perforation interval).

When using an extended-length electric motor and / or hydraulic shielding as part of a pumping unit or when using sectional electric motors, the length of such a casing may exceed the maximum size allowed for transportation by rail and the maximum length of a submersible equipment element that can be lowered into the well (raised from the well) using a standard height mast, with which the elements of the submersible equipment are installed in a vertical position before they are lowered into the well. In this case, composite (sectional) casings are used.

Known composite casing for a submersible centrifugal pump installation, operated below the interval of perforation of the well, described in patent US 6,364,013 B1, E 21 B 43/00, 04/02/2002. The device includes a hollow cylindrical casing, mounted on the inlet module above the inlet of the pump. The casing is made of corrugated sheet

material with the possibility of placing inside it an electric motor of a submersible pump unit so that the flow of formation fluid from the perforation interval will move towards the lower end of the casing along the channels formed by the walls of the production (casing) string and the outer part of the casing corrugations, and then to the pump through the channels formed by the motor housing and the inner part of the corrugations of the casing, providing effective cooling of the electric motor. In this case, the casing corrugations are formed in such a way that ensures the efficient use of the eccentric annular gap between the electric motor and the production casing, that is, the corrugations have a variable value - maximum from the side of the motor current input unit and minimum from the opposite side, thus the axis of the circle described around the outer protrusions of the casing in cross section, will be offset relative to the longitudinal axis of the motor and will coincide with the axis of the circle, which describes the maximum pepper dimension of the electric motor. In the case of using a sectional PED, the casing is made in the form of several sections, mounted directly on the casing of the electric motor sections or connected by special U-shaped elements in section, placed in the corrugations of the adjacent casing sections and fixed on them by screws.

The disadvantages of the analogue is the high complexity of manufacture and low mechanical strength of the casing, due to the need to use for the manufacture of casing sheet material suitable

for making corrugations. In addition, the presence of corrugations around the entire perimeter of the casing, including in the narrowest part of the gap between the SEM and the production string, does not allow the use of such a casing with a standard SEM in a well with an internal diameter of 130 mm.

The closest analogue for both technical solutions from the claimed group of utility models is a composite casing for a submersible centrifugal pump installation and a coupling for connecting casing sections described in the certificate for utility model RU 46532 U1, 10.07.2005 E 21 B 43/00. The casing includes a hollow cylindrical body made with the possibility of placing an electric motor of a submersible centrifugal pump unit inside it in such a way that the flow of the pumped liquid through the gap between the casing and the electric motor is provided, means for securing the upper casing end when the pump unit is placed in the well above the pump inlet with the flow of formation fluid to the pump through the free lower end of the housing. The housing of the casing consists of at least two cylindrical sections connected to each other by means of a coupling, which includes a cylindrical sleeve with centralizers installed inside.

The main disadvantages of the prototype is the complexity of the connection sections of the casing and a significant complication (inability to conduct) operations of lowering and lifting the pump unit equipped with such

casing, in wells with an inner diameter of production casing less than 168 mm and in wells, the curvature requirements of which were not fully observed.

Thus, the task to which the claimed group of utility models is directed is to create a casing for a submersible centrifugal pump installation equipped with an electric motor (hydraulic protection) of increased length and / or a sectional electric motor.

The technical result achieved during the implementation of the first technical solution from the claimed group of utility models is to simplify the process of assembly of the casing during installation of the pump unit in the well.

The technical result achieved by the implementation of the second technical solution from the claimed group of utility models is to expand the scope of use of composite housings and reduce the drop in efficiency of the pump unit equipped with a composite housing by providing sufficient passage for normal flow of fluid in the coupling location zone for coupling sections the casing without a significant reduction in the mechanical strength of the coupling, including with a limited diametrical dimension of the casing and the coupling.

The composite casing of a submersible centrifugal pump installation includes a hollow cylindrical body made with the possibility of placing an electric motor of a submersible centrifugal pump installation inside it so that it is possible to move

the flow of the pumped liquid through the gap between the casing and the motor, and means for securing the top when placing the pump installation in the well of the end of the casing of the casing above the inlet of the pump with the movement of at least the main flow of formation fluid to the pump through the lower end of the casing. The housing of the casing consists of at least two cylindrical sections, made with the possibility of connection using a sleeve, which includes a cylindrical sleeve. Moreover, in contrast to the prototype, at least one end of the sleeve is made with a landing section such that it is possible to place the end part of the housing section with coverage of the coupling landing section. Through radial holes are made on the said end part of the section, and radial holes are made on the coupling seating section with the possibility of coaxial arrangement with the holes of the section and with the possibility of placing embedded elements in said holes for fixing the coupling relative to the section in the axial direction.

In addition, in the particular case of the implementation of the first utility model of the claimed group, each embedded element consists of two parts, the first of which corresponds to the hole in the end of the section, and the second part of the embedded element corresponds to the hole in the fitting section of the coupling.

Moreover, in the particular case of the implementation of the first utility model of the claimed group, the hole area in the fitting section of the coupling is less than the hole area in the end part of the section, while the embedded elements

made with the possibility of fixing on the connected sections in a radial direction with respect to the longitudinal axis of the housing using fasteners placed within sections of the second part of the embedded element, extending beyond the first part of the embedded element.

Moreover, in the particular case of the implementation of the first utility model from the claimed group, the corresponding part of the embedded element is placed in the radial hole of the coupling without a gap.

Moreover, in the particular case of the implementation of the first utility model from the claimed group, the radial holes of the coupling and the corresponding part of the embedded elements have a cylindrical shape.

In addition, in the particular case of the implementation of the first utility model of the claimed group, one end of the cylindrical sleeve of the coupling is connected to the end part of the housing section by welding.

In addition, in the particular case of the implementation of the first utility model of the claimed group, the means for securing the upper end of the casing are made in such a way that they provide installation of the casing with a displacement of its longitudinal axis relative to the longitudinal axis of the motor shaft in the direction of the motor current input assembly.

Moreover, in the particular case of the implementation of the first utility model from the claimed group, means for securing the upper end of the casing body ensure its installation in such a way that the longitudinal axis of the body coincides with the axis of the circle describing the maximum transverse dimension

electric motor.

In addition, in the particular case of the implementation of the first utility model of the claimed group, the means for securing the upper end of the casing body include an input module of the pump of a submersible pump unit, on the external surface of which a cylindrical installation neck is made, which is designed to substantially seal the internal surface of the upper surface on it open end of the housing, and means for fixing the upper open end of the housing to the mounting neck.

Moreover, in the particular case of the implementation of the first utility model of the claimed group, the longitudinal axis of the inner bore of the sleeve of the coupling is shifted relative to the longitudinal axis of the outer cylindrical surface of the sleeve so that it coincides with the longitudinal axis of the motor shaft when it is placed in the casing.

Moreover, in the particular case of the implementation of the first utility model of the claimed group, the inner bore of the sleeve is made in such a way that the gap formed between the inner hole of the sleeve and the outer surface of the motor housing provides a limitation of the deflection of the middle part and the radial movement of the lower end of the housing if the position of the pump unit in the well is different from vertical.

In addition, in the particular case of the implementation of the first utility model from the claimed group, the coupling is equipped with a radially located pin protruding beyond the outer surface of the coupling, and at the end part

sections made longitudinal open on the bottom side of the groove, made with the possibility of placing a pin in it at a given angular position of the section of the casing and the coupling.

The coupling for connecting sections of the casing of a submersible centrifugal pump installation includes a cylindrical sleeve. At the same time, in contrast to the prototype, at least one end of the sleeve is made with a landing section such that it is possible to place it in the cavity of the section of the casing with covering the landing section of the coupling with the end part of the section of the casing and the possibility of fixing the coupling relative to this section in the axial direction. On the inner surface of the sleeve there are made axially oriented grooves open at both ends for the passage of the pumped liquid, and at least part of the length of the fitting section of the coupling grooves are made through.

Moreover, in the particular case of the implementation of the first utility model of the claimed group, radial holes are made between the grooves on the landing section of the coupling between the grooves with the possibility of coaxial arrangement of the coupling holes and the corresponding holes of the casing section and with the possibility of placing embedded elements in these holes for fixing the coupling relative to the section in the axial direction.

Moreover, in the particular case of the implementation of the first utility model of the claimed group on the outer surface of the landing section, the sleeve is made of thread designed to fix the coupling relative to the section.

In addition, in the particular case of the implementation of the first utility model of the claimed group, the longitudinal axis of the inner bore of the sleeve is offset from the longitudinal axis of the outer cylindrical surface of the sleeve so that it coincides with the longitudinal axis of the motor shaft when it is placed in the casing.

Moreover, in the particular case of the implementation of the first utility model of the claimed group, the inner bore of the sleeve is made in such a way that the gap formed between the inner hole of the sleeve and the outer surface of the motor housing provides a limitation of the deflection of the middle part and / or radial movement of the lower end of the housing if the position of the pump unit in the well differs from the vertical.

Moreover, in the particular case of the implementation of the first utility model of the claimed group, the grooves are distributed along the part of the perimeter of the inner hole of the cross section of the sleeve, formed by a half circle bounded by the axis of the cross section of the sleeve perpendicular to the radius along which the longitudinal axis of the outer cylindrical surface of the sleeve is offset.

In addition, in the particular case of the implementation of the first utility model of the claimed group, one end of the cylindrical sleeve is made with the possibility of connection with the end part of the housing sections by welding.

The connection of the housing sections using embedded elements, that is, without moving the connected section relative to the coupling during assembly

housing provides a significant simplification of the assembly process of the casing during installation of the pumping unit in the well.

The presence of grooves for the passage of the pumped fluid, made through in the area by which the outer surface of the clutch is adjacent to the inner surface of the section of the casing body, allows maximum use of the space inside the casing and to form a passage section in the clutch location zone that is sufficient for the normal flow of the pumped fluid without reducing mechanical strength couplings. This avoids a significant increase in hydraulic resistance when the pumped fluid moves to the pump intake and, accordingly, reduces the efficiency of the pumping unit, and also allows for the use of a casing with the described coupling in wells with production casing diameters less than 168 mm.

The possibility of implementing a utility model, characterized by the above set of features, is confirmed by the description of the composite (sectional) casing of the submersible centrifugal pump unit and the coupling for connecting the casing sections made in accordance with this utility model.The description is accompanied by graphic materials that depict the following.

Figure 1 presents a schematic representation of a submersible centrifugal pump installation with the claimed casing,

Figure 2 shows a section of the casing in the area of the coupling,

Figure 3 shows a view a of Figure 2,

Figure 4 shows a section bb of Figure 3 (embedded elements are not conventionally shown).

The composite (sectional) casing 1 is designed to cool the sectional electric motor 2 of the submersible pump unit 3, operated below the perforation interval 4 of the well, and / or to increase the stability of the pump unit when operating wells with a high gas factor or to install a downhole filter, liner on the pump unit for sump cleaning, etc.

The casing 1 includes a hollow cylindrical body 5 and an input module 6 of the pump.

The housing 5 consists of two cylindrical sections 5a and 5b, connected to each other by means of a coupling 8. If it is necessary to install the casing on an electric motor having more than two sections, or on an electric motor (hydraulic protection) of increased length, the number of casing sections can be increased to three or more . The total length of the casing is selected so that the lower end of the motor 2 is located inside the casing 1.

Sections 5a and 5b of the housing of the casing 1 are made of pipe, the diameter of which must exceed the maximum transverse dimension of the electric motor 2 by the amount necessary to ensure easy installation of the casing on the electric motor and lowering the unit into the production casing, in particular for the electric motor of the PED series with a diameter of 103 mm and a maximum transverse dimension 110 mm, lowered into the borehole with an internal diameter

production casing 130 mm, the diameter of the casing will be 124 mm.

The coupling 8 includes a cylindrical sleeve 9, the upper part of which is a landing section 10, the outer diameter of which corresponds to the inner diameter of the section 5A of the housing.

When connecting the sections of the casing 1, carried out at the wellhead before the descent of the pump unit, the coupling 8 is connected to the section 5A, placing the end of the section with the coverage of the landing section of the coupling. The end part of the housing section 5a is firmly adjacent to the surface of the landing portion 10 around the entire perimeter, and the lower end of the section 5a and the adapter 7 of the sleeve 9, which is designed to be mounted on the coupling of the second section (see below), are made with bevels 25 in the direction of movement of the pumped liquids, in such a way as to ensure minimal flow through the gap between them. This ensures the movement of the main flow of the pumped medium from the perforation interval 4 to the intake 19 of the pump through the lower open end of the casing 5.

At the said end part of the section, through radial holes 11 are made having a rectangular shape, and at the landing section of the coupling, through radial cylindrical holes 12 are made, which, when assembling the casing, are aligned with the openings 11 of the housing section and place embedded elements 13 in said holes for fixing the coupling relative to the section in the axial direction.

Each embedded element 13 consists of two parts, the first of which 13a corresponds to a hole in the mounting section of the section, and this part of the embedded element in the assembled state is placed in the hole 11 with a gap, and the second part 13b of the embedded element corresponding to the hole 12 in the mounting section of the coupling 8 placed in the specified hole without a gap. The area of the holes 12 is smaller than the area of the holes 11 made on the end of the section, and the embedded elements are fixed on the connected sections in a direction radial to the longitudinal axis of the housing with screws 14 located within the sections of the second part of the embedded element outside the first part mortgage element.

The lower end of the cylindrical sleeve 9 may be connected to the upper end part of the housing section 5b in the manufacture of this housing section, for example by welding. The coupling of the clutch 8 and the section 5b of the casing body can be realized using a detachable connection as described above.

On the inner surface of the sleeve there are made axially oriented grooves 15 open at both ends for passage of the pumped liquid, moreover, in the area of the landing section 10, the grooves 15 are made through and the holes 12 are made between the grooves.

Each embedded element 13 is made with a threaded hole that is closed by a plug 16 and is intended to facilitate the extraction of the embedded element when disassembling the housing 5.

The upper open end of the section 5a relative to the wellhead is fastened by four bolts on the input module 6 above the receiving grid 19, while a special cylindrical mounting neck is made on the input module, the longitudinal axis of which is offset by the amount relative to the longitudinal axis of the pump input module in the direction of the current input unit 2 e, equal to the distance from the longitudinal axis of the electric motor to the middle of the segment connecting the most protruding part of the current input node of the electric motor and opposite the walls ku of the motor housing, while the longitudinal axis of the mounting neck will coincide with the axis of the circle, describing the maximum transverse dimension of the motor. The inner surface of the upper part of section 5a is tightly adjacent to the surface of the installation neck along the entire perimeter (except for the area where the groove is made in the installation neck for the cable extension cable of the cable line of the submersible pump unit), which ensures the movement of the main flow of the pumped medium through the lower open end casing 5. The installation neck can be made on the basis of the lower pump section, but to maintain the unification of the bases of the pump sections, the preferred option mounting the casing precisely on the input module of the pump.

Due to the eccentric shape of the annular gap between the casing 5 and the motor 2, the hydraulic resistance to fluid movement inside the casing is reduced by 25% compared with the hydraulic resistance created by currently used similar devices

with a concentric annular gap between the casing and the electric motor. Thus, in comparison with the known devices, the hydraulic resistance at the inlet of the centrifugal pump is significantly reduced and, accordingly, the efficiency of the pump unit is increased, and the likelihood of transition of the pump stages to the cavitation mode, which translates into a feed failure, is also reduced. When installing the casing in a large-diameter production casing, the need for displacement of the casing axis will be determined only by the possibility of reducing the hydraulic resistance at the inlet of the centrifugal pump, and the amount of displacement will be determined from the condition for the pumped medium to pass between the casing and the motor housing around the entire perimeter of the electric motor.

The longitudinal axis of the inner hole of the sleeve 9 is also offset by an amount e relative to the longitudinal axis of the outer cylindrical surface of the sleeve, so that it coincides with the longitudinal axis of the motor shaft, thus the coupling 8 acts as a centralizer, limiting the deflection of the middle part and the radial movement of the lower end of the casing, in the event that the position of the pump unit in the well differs from the vertical.

The grooves 15 are distributed along part of the perimeter of the cross section of the inner hole of the sleeve of the sleeve, formed by a half circle bounded by an axis O ₁ O _{2 of the} cross section of the sleeve perpendicular to the radius along which the longitudinal axis of the inner hole of the sleeve is offset (see Figure 4).

The clutch 8 is also equipped with a radially oriented pin 17, protruding beyond the outer surface of the clutch, and on the end of the section 15a there is a longitudinal groove 18 open on the lower side, made with the possibility of placing the pin 17 therein at a given angular position of the casing section and the clutch. The pin 17 and the groove 18 are designed to ensure the connection of the sections of the housing 5 only in a predetermined angular position, which is necessary to combine the eccentricities of the mounting neck of the input module and the inner hole of the coupling 8, as well as to ensure the tolerance of the holes 11 and 12.

In the lower part of the coupling 8, coaxial holes 26 are made for fixing the clamp holding the section 5b with the coupling 8 connected to it at the wellhead during assembly of the casing before the pump unit is launched.

In the event that the pump unit is used in a well with a high content of mechanical impurities in the formation fluid, the casing 5 can be equipped with a special tool for cleaning the sump from the mechanical particles accumulating in it. The specified tool is a hollow cylindrical shank (not shown in the drawings), the upper open end of which is fixed inside the casing from the side of its lower end to ensure the flow of the pumped medium through the lower open end of the shank, while the diameter of the shank should be less than the diameter of the casing. In addition, in the case of using a shank, it is possible to place the unit so that the pump unit 3 is located inside the production string above the perforation interval, and the lower

the end of the liner is lowered below the specified interval, where the casing often has a smaller diameter than in the main part of the well, which does not allow placing the pump unit with a casing there, while retaining the advantages associated with the possibility of lowering the bottomhole pressure, as well as the ability to clean the sump as described above way.

The shank can also be used to place a downhole filter (see, in particular, RU 46532 U1, 2005.07.10, RU 2230181 C2, 10.06.2004), etc.

The device operates as follows.

The flow of formation fluid from the perforation interval 4 of the well due to the depression created by the pump unit moves in the direction of the lower end of the casing 5, passing through the annular gap between the casing and the production string, while natural gas separation occurs between the perforation interval and the lower end of the casing, and the well acts as a natural gas separator.

Once inside the lower section of the casing 5, the formation fluid passes through the hollow shaft 20 and the holes 21 and enters an eccentric annular gap between the casing 5 and the motor 2. The fluid flow washes the wall of the housing of the electric motor 2, providing cooling, and then gets to the pump 19, while the pressure at the pump intake is increased due to the increased depth of the pump, which allows to stabilize the operation of the centrifugal pump.

In that case, if a casing with a liner is used, the formation stream

getting into the liner increases its speed, due to the fact that the internal cross-sectional area of the liner is less than the annular cavity between the liner and the production string, while particles of solids deposited in the bottomhole zone are captured by the flow of the pumped medium and carried to the surface by a centrifugal pump, which slightly reduces the resource of the pump, but increases the life of the well.

Claims (19)

1. Composite casing of a submersible centrifugal pump installation, including a hollow cylindrical body, configured to accommodate an electric motor of a submersible centrifugal pump installation inside it in such a way that the flow of the pumped liquid through the gap between the casing and the motor and means for securing the upper the placement of the pump installation in the well of the end of the casing body above the inlet of the pump with the movement of at least the main the flow of reservoir fluid to the pump through the lower end of the housing, while the housing of the casing consists of at least two cylindrical sections made with the possibility of connection using a sleeve that includes a cylindrical sleeve, characterized in that at least one end of the sleeve is made with a landing section such that it is possible to place an end portion of a section of the housing with a coverage of the landing section of the coupling, while through said radial holes are made And on the mounting sleeve portion provided with radial holes to be coaxial with hole section and to be arranged in said openings of the fitting members, for securing the sleeve relative to the section in the axial direction. 2. The casing according to claim 1, characterized in that each embedded element consists of two parts, the first of which corresponds to the hole in the end of the section, and the second part of the embedded element corresponds to the hole in the fitting section of the coupling 3. The casing according to claim 2, characterized in that the area of the hole in the fitting section of the clutch is less than the area of the hole in the end of the section, while the embedded elements are made with the possibility of fixing on the connected sections in a radial direction with respect to the longitudinal axis of the housing using fasteners placed within areas of the second part of the embedded element, extending beyond the first part of the embedded element. 4. The casing according to claim 2, characterized in that the corresponding part of the embedded element is placed in the radial hole of the coupling without a gap. 5. The casing according to claim 4, characterized in that the radial holes of the coupling and the corresponding part of the embedded elements have a cylindrical shape. 6. The casing according to claim 1, characterized in that one end of the cylindrical sleeve of the coupling is connected to the end part of the housing section by welding. 7. The casing according to claim 1, characterized in that the means for securing the upper end of the casing of the casing are made in such a way as to ensure the installation of the casing with a shift of its longitudinal axis relative to the longitudinal axis of the motor shaft in the direction of the current drive assembly of the electric motor. 8. The casing according to claim 7, characterized in that the means for securing the upper end of the casing of the casing ensure its installation so that the longitudinal axis of the casing coincides with the axis of the circle describing the maximum transverse dimension of the electric motor. 9. The casing according to claim 1, or 7, or 8, characterized in that the means for securing the upper end of the casing of the casing include an input module of the pump of a submersible pump unit, on the outer surface of which a cylindrical mounting neck is made, intended for a substantially tight installation on it the inner surface of the upper open end of the housing, and means for fixing the upper open end of the housing on the mounting neck. 10. The casing according to claim 7, characterized in that the longitudinal axis of the inner hole of the sleeve of the coupling is offset from the longitudinal axis of the outer cylindrical surface of the sleeve in such a way that it coincides with the longitudinal axis of the motor shaft when it is placed in the casing. 11. The casing of claim 10, characterized in that the inner bore of the sleeve is made in such a way that the gap formed between the inner hole of the bushing and the outer surface of the motor housing provides a limitation of the deflection of the middle part and the radial movement of the lower end of the casing if the position of the pump unit is well differs from vertical. 12. The casing according to claim 1, characterized in that the clutch is provided with a radially located pin protruding beyond the outer surface of the clutch, and on the end of the section there is a longitudinal groove open from the lower side, made to accommodate the pin in it at a given angular position of the section casing and couplings. 13. A clutch for connecting sections of the casing of a submersible centrifugal pump installation, including a cylindrical sleeve, characterized in that at least one end of the sleeve is made with a landing section such that it is possible to place it in the cavity of the section of the housing with the coverage of the landing section of the coupling the end part of the casing section and the possibility of fixing the coupling relative to this section in the axial direction, axially oriented grooves open from both ends are made on the inner surface of the sleeve A passage of the pumped fluid, and, on at least part of the length of the seating section sleeve formed with through slots. 14. The clutch according to claim 13, characterized in that radial holes are made between the grooves on the landing section of the coupling with the possibility of coaxial arrangement of the coupling holes and the corresponding holes of the casing section and with the possibility of placing embedded elements in said holes for fixing the coupling relative to the section in axial direction. 15. The coupling according to item 13, wherein the sleeve is made on the outer surface of the landing section of the sleeve, designed to fix the coupling relative to the section. 16. The coupling according to item 13, wherein the longitudinal axis of the inner hole of the sleeve is offset relative to the longitudinal axis of the outer cylindrical surface of the sleeve so that it coincides with the longitudinal axis of the shaft of the motor when placing it in the casing. 17. The coupling according to clause 16, wherein the inner hole of the sleeve is made in such a way that the amount of clearance formed between the inner hole of the sleeve and the outer surface of the motor housing provides a limitation of the deflection of the middle part and / or radial movement of the lower end of the casing if the position the pumping unit in the well differs from the vertical one. 18. The sleeve according to clause 16, characterized in that the grooves are distributed along the part of the perimeter of the inner hole of the cross section of the sleeve, formed by a half circle bounded by the axis of the cross section of the sleeve perpendicular to the radius along which the longitudinal axis of the outer cylindrical surface of the sleeve is offset. 19. The coupling according to item 13, wherein one end of the cylindrical sleeve is made with the possibility of connection with the end part of the sections of the housing by welding.