WO2022045923A1

WO2022045923A1 - Downhole multi-stage trochoid pump

Info

Publication number: WO2022045923A1
Application number: PCT/RU2021/000028
Authority: WO
Inventors: Иван Соломонович ПЯТОВ; Сергей Викторович ЛАДАНОВ; Виктор Геннадьевич ТИМОШЕНКО; Владимир Николаевич Ивановский; Алексей Михайлович ДОНЧЕНКО; Владимир Игоревич ФЕДОРЕНКО
Original assignee: Общество с ограниченной ответственностью "РЕАМ-РТИ"
Priority date: 2020-08-26
Filing date: 2021-01-25
Publication date: 2022-03-03
Also published as: RU2739932C1

Abstract

The invention relates to downhole multi-stage trochoid pumps for pumping formation fluid out of wells. The present pump consists of trochoid stages comprising a stator, and an inner and an outer rotor mounted for internal engagement and conjoint rotation. The rotors are mounted on a shaft such as to be fixed in a circumferential direction and not fixed in an axial direction and such as to be eccentric relative to the stators, being mounted in an axial sliding bearing. In adjacent stages, the rotors are offset in a circumferential direction by an angle of 180°. The shaft is mounted in bearing assemblies. The stages are separated by a guide apparatus having a through-hole and two blind holes separated by a partition. The through hole connects the outlet of a lower stage to the inlet of the stage above. The stator of a stage is provided with two bypass ports, one of which connects the outlet of the stage to a blind hole of the guide apparatus below, and the other of which connects the inlet of the stage to a blind hole of the guide apparatus above. The invention is intended to increase the operating reliability and service life of a multi-stage trochoid pump.

Description

DOWNHOLE MULTI-STAGE TROCHOID

PUMP

The invention relates to petroleum engineering, in particular to multistage submersible pumps for pumping reservoir fluid from wells.

Known multi-stage rotary pump contains a housing closed with end caps, and placed inside the housing cavity, at least one shaft mounted on bearings, and rotors rigidly mounted on the shaft, separated by radial partitions fixed on the housing, with the formation of successive compression stages of the working medium, made with working chambers and suction and discharge windows communicated with the inlet and outlet fittings by means of channels, respectively, and the discharge window of each working medium compression stage is connected with the suction window of the adjacent stage, following in the direction of the working medium flow. The rotors of each pump stage are made with internal gearing, the tooth of each of the internal rotors being in full engagement with the external rotor. In adjacent stages of compression of the working medium, the outer rotors are displaced in the circumferential direction by an angle equal to 180°. The outer rotor is made with internal teeth, and the inner rotor, rigidly mounted on the shaft, is made with eccentricity relative to the outer rotor and is equipped with external teeth, the number of which is one less than the number of teeth of the outer rotor (according to patent RU55896, IPC F04C 13/00, publ. 27.08 .06). The disadvantage of this pump is that the fluid enters and exits the stages perpendicular to the axis of the pump, which increases the diameter of the pump and limits its use in the well.

The closest technical solution is the installation of a gerotor pump, which is used to produce formation fluid from a well. The drive is carried out from the submersible electric motor. The pump contains at least one stage consisting of inner and outer rotors rotating in plain bearings. The inner rotor is mounted on the shaft. The rotors rotate between discs having inlet and outlet holes (according to the patent US20150071795, IPC F04C 23/02, publ. 12.03.15).

The disadvantage of this installation is the uneven impact of axial forces arising from pumping fluid and acting on the stage rotors. This can cause increased wear on the rotors.

The technical result achieved by using the invention is to increase the reliability of operation and service life of a multistage trochoid pump due to the applied design solutions.

The specified technical result is achieved by the fact that the downhole multistage trochoid pump consists of two or more trochoid stages, including a stator with end-mounted covers with inlet and outlet holes on each, inner and outer rotors installed with internal engagement and the possibility of mutual rotation, and differs in that the inner rotors are mounted on the shaft with fixation in the circumferential direction and without fixation in the axial direction, and the outer rotors are installed with eccentricity in the stators of the steps in the axial plain bearing, in adjacent steps the outer rotors are displaced in the circumferential direction by an angle equal to 180°, the shaft is mounted in bearing supports, the trochoid stages are separated by a guide vane, in which one through hole and two blind holes are made, separated by a partition, the through hole connects the outlet below the installed stage with the inlet above the installed stage, while the stator of the stage has two bypass channels, one of which connects the stage outlet with a blind hole below the installed guide vane, and the other connects the stage inlet with a blind hole above the installed guide vane.

In addition, filter elements can be installed in the bypass channels.

In addition, the bypass channel may be connected to the sleeve bearing of the outer rotor.

In addition, the inner rotor can be mounted on a shaft with radial clearance.

In addition, the pump may additionally contain upstream devices: an inlet module, a gas separator, a filter module, which can be equipped with filter elements, including those made of a wire-permeable material.

In addition, the rotors can be made from a ceramic-like material.

The present invention is illustrated by the following drawings, which show:

Fig. 1 - borehole multistage trochoid pump, longitudinal section;

Fig. 2 - assembled trochoid stage design;

Fig. 3 - disassembled design of the trochoid stage; Fig. 4 - downhole multistage trochoid pump in the well;

A multistage trochoid pump (Fig. 1) consists of trochoid stages 1, each of which consists of a stator 2, an inner rotor 3, an outer rotor 4. The outer rotor 4 is installed with eccentricity relative to the stator 2 in an axial plain bearing 5. The inner rotor 3 is mounted on shaft 6 without fixation in the axial direction and with fixation in the circumferential direction by means of flats 7. Shaft 6 is installed in bearing supports 8, Trochoid steps 1 are separated by a guide vane 9, connecting through a through hole 10 outlet 11 below the set stage with inlet 12 above the set stage . The stator 2 has two bypass channels 13 and 14 (Fig. 2). The bypass channel 13 connects the blind hole 15 in the guide vane 9 with the inlet of stage 12, and the bypass channel 14 connects the blind hole 16 with the outlet of stage 11 (Fig. 3).

The downhole multistage trochoid pump 17 (Fig. 4) is part of the downhole pump installation, which, in addition to the pump 17, consists of a submersible motor 18, hydraulic protection 19, input module

20. The unit is connected to the tubing string (tubing)

21 attached to the wellhead. Submersible motor 19 is powered by cable 22. Input module 20 can be equipped with filter elements 23.

Downhole multistage pump operates as follows. The pump 17 as part of the installation descends into the well on the tubing string 21. The cable 23 supplies power to the electric motor 18, which transmits torque to the shaft 6 of the pump 17. The inner rotor 3 rotates together with the shaft 6 and, due to engagement with the outer rotor 4, transmits rotation and on him. As a result, the liquid is transferred from the inlet 12 to the outlet 11 of the stage and enters through the through hole 10 of the guide vane 9 to input 12 of the next stage, where the process is repeated. The liquid enters the input 12 of the lower stage of the pump through the input module 20. After passing through all the stages, the liquid enters the tubing string 21 and is pumped to the surface.

Due to the presence of bypass channels 13 and 14, the pressures are equalized and, as a result, the axial forces acting on the stage rotors.

A filter element (not shown in the figure), which can be installed in the bypass channels, prevents the accumulation of mechanical impurities in the bypass channel.

The bypass channel may be connected (not shown in the figure) to the outer rotor plain bearing to provide fluid friction.

The use of the input module 20 with the filter element 23 makes it possible to purify the liquid from mechanical impurities, which provides protection against wear of the parts of the trochoid stage and other elements of the pump.

The manufacture of rotors from a ceramic-like material increases the reliability of the pump by increasing their wear resistance, which is important when operating in wells complicated by a large amount of mechanical impurities.

Thus, the technical solutions proposed in the invention increase the reliability of operation and the resource of a downhole multistage trochoid pump and contribute to the achievement of a technical result.

Claims

CLAIM

1. Downhole multistage trochoid pump, consisting of two or more trochoid stages, including a stator and inner and outer rotors mounted with internal engagement and the possibility of mutual rotation, and characterized in that the inner rotors are mounted on a shaft with fixation in the circumferential direction and without fixation in the axial direction, and the outer rotors are installed with eccentricity in the stators of the steps in the axial plain bearing, in adjacent steps the outer rotors are displaced in the circumferential direction by an angle equal to 180°, the shaft is installed in bearing supports, the trochoid steps are separated by a guide vane, in which one through hole and two blind holes separated by a partition, the through hole connects the outlet below the installed stage with the inlet above the installed stage, while two bypass channels are made in the stage stator, one of which connects the stage outlet with a blind hole below the installed guide vane, and the other the goy connects the entrance of the stage with a blind hole above the installed guide vane.

2. The pump according to claim 1, characterized in that filter elements are installed in the bypass channels.

3. The pump according to claim 1 or 2, characterized in that the bypass channel is connected to the plain bearing of the outer rotor.

4. The pump according to claim 1 or 2, characterized in that the inner rotor is mounted on a shaft with a radial clearance.

5. The pump according to claim 1 or 2, characterized in that the pump additionally contains upstream devices: an inlet module, a gas separator, a filter module.

6. The pump according to claim 5, characterized in that the filter module is equipped with filter elements made of a wire-permeable material.

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7. The pump according to claim 1 or 2, characterized in that the rotors are made of a ceramic-like material.

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