RU2818221C1 - Borehole centralizer for lowering of electric submersible pump unit - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention is intended for alignment of electric motor of submersible installation of electric submersible pump (ESP). Downhole centralizer for lowering the ESP installation includes a guide tube with an upper tip installed at its ends, having a connecting thread for connection with an ESP electric motor, and a lower end part, a movable bushing, arc-shaped plate springs, and a cylindrical spring arranged between the upper tip and the movable bushing. Upper ends of arc-shaped plate springs are mounted in slots of movable bushing. Lower ends of arc-shaped plate springs are fixed in slots of lower end part made in the form of hollow housing. Guide cone with inclined inlet holes is attached to the lower end part, which is made with a radius curvature of the sharp part to prevent jamming when entering the string with a smaller diameter. Upper tip is equipped with outlet holes.

EFFECT: higher reliability of centralizer, improved alignment of electric motor of ESP unit during lowering into string and guaranteed passage of ESP installation in coupling and non-coupling casing strings and during lowering into side shaft, as well as protection of the cable extension from damage when the ESP installation enters the side shaft.

4 cl, 5 dwg

Description

The invention relates to the oil and gas industry, in particular to equipment for oil production, and is intended for centering the electric motor of a submersible installation

electric centrifugal pump (ESP) during descent into the well, as well as to protect the cable extension when the ESP enters the sidetrack.

A mechanical spring centralizer of the CR type produced [https://vileren.ru/?a=item&id=55] is known, containing a barrel with end parts in the form of upper and lower bushings, centering leaf springs of the spring type, threaded nuts for retaining leaf springs, as well as a retaining ring with a screw.

The disadvantage of the known centralizer of the mechanical spring type CR is the low efficiency of operation in curved wells due to the limited compression stroke of the leaf springs, which are rigidly secured with nuts. A large number of leaf springs (up to 10 pieces) and high rigidity require a significant axial force of up to 340 kN, which limits the depth of descent of the equipment. The design is characterized by a high risk of shearing the screw holding the locking ring during descent, leading to the destruction of the centering lantern and the barrel falling out. In addition, such a centralizer design will not be able to ensure the passage of non-coaxial coupling transitions of columns of different diameters.

As the closest analogue, we selected a mechanical spring centralizer type IS341, manufactured by SJSC NOVINKA, FID group [see. Product catalog New, p29; http://mashoil.ru/wp-content/uploads/2018/12/2018.04.10_%D0%9A%D0%B0%D1%82%D0%B0%D0%BB%D0%BE%D0%B3- %D0%BF%D1%80%D0%BE%D0%B4%D1%83%D0%BA%D1%86%D0%B8%D0%B8_%D0%9D%D0%BE%D0%B2%D0 %B8%D0%BD%D0%BA%D0%B0-1.pdf], containing a guide tube, on the upper part of which a tip is installed using a threaded connection, and a lower end piece in the form of a connecting piece is attached to the lower part using a threaded connection couplings, upper and lower movable bushings, centering leaf springs of the arched type, threaded nuts installed on top of the bushings to hold the fixed ends of the leaf springs in the upper and lower bushings, and two coil springs, one of which is located between the upper bushing and tip, and the second - between the lower sleeve and the coupling.

The disadvantage of the known spring centralizer is the low efficiency of operation in curved wells due to the limited compression stroke of the leaf spring arc, the need to maintain significant accuracy in the manufacture of seats in the upper and lower bushings and in the threaded nuts for installing and fixing the leaf springs. The high rigidity of leaf springs requires a significant axial force of up to 100 kN, which creates a limitation on the depth of descent of the equipment and requires the installation of two cylindrical springs to create axial forces to counteract the movement of the bushings when compressing the leaf springs. In addition, such a centralizer design will not be able to ensure the passage of non-coaxial coupling transitions of columns of different diameters.

The technical result of the invention is the development of a reliable device that ensures guaranteed passage of the ESP in sleeved and sleeveless casing strings, passage of the ESP when lowering into the sidetrack, centering of the ESP electric motor during descent into the string, protection of the cable extension from damage when the ESP enters the sidetrack.

The specified technical result is achieved by the fact that in the downhole centralizer for lowering the installation of an electric centrifugal pump, which includes a guide tube with an upper tip having a connecting thread and a lower end piece installed at the ends, a cylindrical spring placed between the tip and a movable sleeve into which the upper ends are mounted arcuate leaf springs, according to the invention, the lower ends of the arcuate leaf springs are fixed in the grooves of the lower annular part, which acts as a body, to which is attached a guide cone with inclined inlet holes, made with a radius rounding of the sharp part to prevent jamming when entering a column with a smaller diameter, and the tip is equipped with outlet holes.

It is preferable that the angle at the apex of the guide cone is in the range of 14÷16°.

In this case, the movable sleeve is installed with the ability to slide along the outer diameter of the guide tube along the axis.

To ensure elasticity and plasticity, springs of the spring type are made of steel or precision alloys with an elastic modulus not exceeding 2.18x10 ⁵ MPa.

In addition, the ends of the plate-arc-shaped springs are fixed in hinges and flared with rivets; the plate springs are fixed with the help of axes in the holes of the grooves made in the upper part of the body and in the sleeve.

The proposed centralizer design can be used for running ESP into casing strings with a nominal diameter of 102÷245 mm.

The essence of the invention is illustrated by drawings, in Fig. 1 shows a downhole centralizer, general view; in fig. 2-4 shows the sequence of compression of the centralizer springs during descent, Fig. 5 - operation of the well centralizer when lowering into a non-coaxial string.

The well centralizer (Fig. 1) contains the following parts: plate springs 1, guide cone 2, lower end part in the form of a hollow body 3, guide tube 4, movable sleeve 5, upper tip 6, coil spring 7, axles 8.

Leaf spring 1 is made in the form of a curved arc with hinges, the assembly is made with fasteners - rivets. The leaf spring 1 is made of precision alloys or corrosion-resistant steels, and to ensure the necessary elasticity and longitudinal stability, materials are used whose elastic modulus does not exceed 2.18x10 ⁵ MPa. The material and stiffness of the leaf springs are selected in such a way as to guarantee their reliability when a situation arises when the centralizer takes the load from the weight of the electric motor of the ESP installation onto one leaf spring, ensuring guaranteed passage of the ESP installation in non-coaxial coupling transitions of different diameters of the columns.

Cone 2 is screwed to the bottom of housing 3 and is a cone-shaped structure with a radius rounding of the sharp part, which allows you to guide and ensure unhindered passage of the centralizer into the production string, and also reduces friction forces and eliminates jamming of the ESP installation when entering a string with a smaller diameter. The acute angle at the apex of the guide cone 2 is 14÷16°. In the body of cone 2, inlet openings are made at an angle, designed to allow fluid to pass through and reduce hydraulic resistance when lowering the ESP installation.

Housing 3 has a cylindrical shape with an internal channel for the passage of liquid when lowering the ESP unit and is equipped in the upper part with grooves for fastening the lower ends of the plate springs 1. Housing 3 as part of the centralizer is fixedly fixed using threaded connections on the outer surface of the guide tube 4 and on the inner surface cone 2.

The guide tube 4 is made with an internal passage channel over its entire length and external threads at the ends. A tip 6 is attached to the upper thread, and a housing 3 is attached to the lower thread. The internal passage channel of the guide tube 4 ensures the passage of liquid from the guide cone 2, the hollow body 3 when lowering the ESP installation.

The sleeve 5 is made in the form of a cylinder with grooves on the outer surface for fastening the upper ends of the plate springs 1 and is installed on the guide tube 4 with the ability to move along the axis when the plate springs 1 are compressed during the descent of the ESP installation. An anti-friction coating is applied along the inner diameter of the movable bushing 5, which protects the bushing when moving along the outer diameter of the guide tube 4.

The hinges of the leaf springs 1 are fixed in the holes of the grooves of the hollow body 3 and in the holes of the grooves of the sleeve 5 using axes 8, which are flared to prevent them from falling out and self-unscrewing. The number of plate springs 1 is calculated based on ensuring guaranteed retention of the weight of the electric motor of the ESP installation when entering sidetracks, as well as when entering sidetracks with an offset column.

In the tip 6, which has a cylindrical shape, there is a central internal channel, from which there are outlet openings intended for the passage of liquid when lowering the ESP. In the upper part, tip 6 has a thread for connecting the centralizer to the ESP electric motor.

A cylindrical spring 7 is installed between the tip 6 and the movable sleeve 5.

Depending on the operating conditions, centralizer materials can be selected for various environments, including conditions with the corrosive effects of hydrogen sulfide with simultaneous exposure to stress (SCRN conditions).

The centralizer works as follows:

When installing an ESP, the downhole centralizer is screwed into the base unit of the electric motor, after which the ESP is lowered into the well to the required operating depth.

When lowering the ESP into the well on horizontal, vertical, inclined or curved sections of the column with coupling transitions, the plate springs 1 of the well centralizer, interacting with the internal walls, are compressed and move the sleeve 5 along the axis of the guide tube 4 upward, while the spring 7 is compressed, exerting axial the force to counteract the movement of the sleeve 5, thereby ensuring uniform distribution of the elastic force of the plate springs 1, due to which the ESP is centered relative to the walls of the well or the walls of the adapter couplings (Fig. 2-4).

In the case of passage of non-coaxial coupling transitions of different diameters of the columns, the leaf spring 1 begins to move the sleeve 5, after which the other leaf springs 1 begin to close, overcoming the axial force. Consequently, when the centralizer is supported by one leaf spring 1, the radial stiffness will be maximum, since the force for the axial displacement of the bushing 5 will come from only one leaf spring 1, while the spring 7 and the elastic component of the remaining leaf springs 1 will prevent this displacement, thereby centering the position of the guide cone 2 for unhindered passage (Fig. 5).

When lowering the ESP, a hydraulic resistance force arises from the fluid in the well. To reduce the influence of hydraulic force and the passage of liquid through the entire length of the centralizer, the design has inlet holes in cone 2, an internal channel in the body 3, an internal passage channel in the guide tube 4 and outlet holes in the tip 6.

The proposed centralizer is part of the ESP due to its threaded connection to the base unit of the electric motor, which greatly facilitates installation. Along with this, the design prevents the destruction of the centralizer during descent and increases the reliability of the installation due to effective centering during the passage of curved sections of wells and non-coaxial coupling transitions of different diameters of the column, and also protects the cable extension when the ESP enters the sidetrack.

Claims (4)

1. Downhole centralizer for lowering the installation of an electric centrifugal pump (ESP), including a guide tube with an upper tip installed at its ends, having a connecting thread for connection to the ESP electric motor, and a lower end part, a movable bushing, arcuate leaf springs, a cylindrical spring placed between an upper tip and a movable sleeve into which the upper ends of the arc-shaped leaf springs are mounted, characterized in that the lower ends of the arc-shaped leaf springs are fixed in the grooves of the lower end part, made in the form of a hollow body, to which a guide cone with inclined inlet holes, made with a radius, is attached rounding of the sharp part to prevent jamming when entering a column with a smaller diameter, and the upper tip is equipped with outlet holes. 2. The centralizer according to claim 1, characterized in that the guide cone is made with an apex angle of 14-16°. 3. The centralizer according to claim 1, characterized in that the arched leaf springs of the spring type are made of corrosion-resistant steel or precision alloys with an elastic modulus not exceeding 2.18⋅10 ⁵ MPa. 4. The centralizer according to claim 1, characterized in that the ends of the arc-shaped leaf springs are fixed in hinges and flared with rivets, while the hinges are fixed in the holes of the grooves made in the upper part of the hollow body and in the movable sleeve, by means of axes.