RU63468U1 - STEP OF SUBMERSIBLE MULTISTAGE CENTRIFUGAL PUMP - Google Patents

Abstract

The utility model relates to the field of development of pumps and compressors and can be used in submersible multistage centrifugal pumps for oil production from wells.

The technical result of using the utility model is to increase the efficiency and reliability of the stage of a submersible multistage centrifugal pump, due to the improvement of the dysnergization process when pumping liquid-gas mixtures, especially when extracting oil with a high gas content and in difficult operating conditions of oil wells.

The specified technical result is achieved in that the step of a submersible multistage centrifugal pump consists of an impeller having a hub and vanes, a guide apparatus, upper and lower disks with vanes located between them, forming the flow part of the guide apparatus. At the inlet and outlet of the flowing part of the guide vane, there are respectively inlet and outlet annular chambers that provide hydraulic communication between the flowing parts of the impeller and the guide vane. The impeller blades have inlet portions elongated to the hub and arranged in a circle to form an axial circular grid. The elongated sections of the impeller blades may have protrusions located circumferentially below the upper disk of the guide apparatus and rotating in the output annular chamber of the guide apparatus. The guide apparatus can be collapsible. In this case, the upper disk of the guide vane is removable. The impeller is designed as an open type wheel and is equipped with blades mounted directly on the hub. A centering bearing can be installed between the shaft and the guide vane.

The specified technical result is achieved in that the step of a submersible multistage centrifugal pump consists of an open impeller having a hub and vanes, a guide apparatus having an upper disk and a lower disk with vanes located between the disks forming the flow part of the guide apparatus. At the inlet and outlet of the flowing part of the guide vane, the inlet and outlet annular chambers are made respectively, which provide hydraulic connection of the flowing parts of the impeller and the guide vane. The impeller blades have inlet portions elongated to the hub and arranged in a circle to form an axial circular grid. Through-holes are made in the guide apparatus, communicating the flowing part of the impeller with the flowing part of the guide apparatus or with the flowing part of the impeller of an adjacent stage, with the possibility of periodically blocking these openings with the blades of the impeller during its rotation.

Possible versions of the submersible multi-stage centrifugal pump stage;

- through holes are made in the upper disk of the guide vane, communicating the flowing part of the guide vane of one stage with the flowing part of the impeller of the next stage installed above.

- through holes are made in the lower disk of the guide vane, communicating the flowing part of the guide vane with the flowing part of the impeller.

- in the guiding apparatus, through holes are made passing through the upper disk, vanes of the guiding apparatus and the lower disk, providing direct communication of the flowing part of the impeller of one stage with the flowing part of the impeller of the next stage.

Description

The utility model relates to the development of pumps and compressors and can be used in submersible multistage centrifugal pumps for oil production from wells.

A dispersing step of a submersible multistage centrifugal pump is known, comprising a guiding apparatus and an open impeller installed in the guiding apparatus, the blades of which are located on the lower surface of the drive disc, in which holes are made in the spaces between the fastening points of the blades, and the distance from the lower edge of each of the blades to the upper surface of the upper disk of the guide vane increases in the direction from the inner edge of the lower edge of the blade to the outer edge of the specified blade edges. [RF patent 2209347 from 06.22.2001; F04D 13/10, F04D 31/00]

The volumetric flow rate of the medium flowing through the dispersing holes in the impeller depends on the pressure drop and, therefore, on the operating mode of the pump itself. Thus, the effectiveness of such a dispersing device decreases with an increase in pump flow and a decrease in pressure drop. Such a dispersing device does not have an adjustment system for changing pump operating conditions.

Closest to the claimed technical solution is the step of a submersible multistage centrifugal pump, consisting of an impeller having a hub and vanes, a folding guide vane having a removable upper disk and a lower disk with vanes placed between the disks forming the flow part of the guide vane. Inlet and outlet flow

the parts of the guide apparatus are respectively made of the input and output annular chambers, which provide hydraulic communication of the flowing parts of the impeller and the guide apparatus. The impeller blades have inlet portions elongated to the hub and arranged in a circle to form an axial circular grid. The axial grate provides a reversal of the flow at the entrance to the impeller, and in addition provides the performance of the dispersant. Between the contacting horizontal surfaces of the impeller and the guide vane axial bearings are installed. [Application No. 2006124211/22 (026252) dated 07/05/2006; F04D 13/10].

A disadvantage of the known device is that the mixing of the liquid with gas, that is, dispersion, is provided only due to the vortices formed during the flow around the axial lattice with a liquid-gas stream. Such a dispersing device does not have an adjustment system for changing pump operating conditions.

The technical result of using the utility model is to increase the efficiency and reliability of the stage of a submersible multistage centrifugal pump, due to the improvement of the dispersion process during the pumping of liquid-gas mixtures, especially when producing oil with a high gas content and in difficult operating conditions of oil wells. In addition, the technical solution should allow to regulate, adjust the dispersion system taking into account the operating conditions of the pump. In addition, the technical solution should simplify and reduce the cost of the technology for manufacturing stage components.

The specified technical result is achieved in that the step of a submersible multistage centrifugal pump consists of an open impeller having a hub and vanes, a guide

apparatus having an upper disk and a lower disk with blades placed between the disks forming the flow part of the guide apparatus. At the inlet and outlet of the flowing part of the guide vane, the inlet and outlet annular chambers are made respectively, which provide hydraulic connection of the flowing parts of the impeller and the guide vane. The impeller blades have inlet portions elongated to the hub and arranged in a circle to form an axial circular grid. Through-holes are made in the guiding apparatus, communicating the flowing part of the impeller with the flowing part of the guiding apparatus or with the flowing part of the impeller of an adjacent stage, with the possibility of periodically blocking these openings with the blades of the impeller during its rotation.

Possible versions of the submersible multistage centrifugal pump stage:

- through holes are made in the upper disk of the guide vane, communicating the flowing part of the guide vane of one stage with the flowing part of the impeller of the next stage installed above.

- through holes are made in the lower disk of the guide vane, communicating the flowing part of the guide vane with the flowing part of the impeller.

- in the guiding apparatus, through holes are made passing through the upper disk, vanes of the guiding apparatus and the lower disk, providing direct communication of the flowing part of the impeller of one stage with the flowing part of the impeller of the next stage.

The shape and size of the holes can act as regulatory parameters. The upper disc with the simplest geometric shapes can be used as a replacement part. Having a set of upper disks with different opening areas, when assembling the pump, you can adjust and adjust the dispersion system, taking into account the operating conditions of the pump.

The set of essential features of the claimed technical solution can be reused in the manufacture of pumps.

The technical result consists in increasing the efficiency and reliability of the pump due to the efficiency of dispersion of mixtures of liquids and gases. The claimed technical solution provides a simplification of the manufacture of the structure with the availability of regulation and adjustment of the dispersion system.

These advantages, as well as the features of this technical solution will become clear when considering options for its implementation with reference to the accompanying drawings.

The figure 1 shows a section of two stages in the Assembly.

The figure 2 shows a cross section of a multistage submersible centrifugal pump with a view of the wheel from the side of its entrance.

The figure 3 shows the step of a variant of a submersible multistage centrifugal pump, in which the holes in the guide apparatus are made in the upper disk. The upper disc and wheel are shown in a raised position. A segment is conventionally cut from the upper wheel and the guide apparatus.

The figure 4 shows the step of a variant of a submersible multistage centrifugal pump, in which the holes in the guide apparatus are made in the lower disk. Upper disc and wheel

depicted in a raised position. A segment is conventionally cut from the upper wheel and the guide apparatus.

The figure 5 shows the step of a variant of a submersible multistage centrifugal pump, in which the holes in the guide apparatus are made in the upper disk, blades and lower disk. A segment is conventionally cut from the upper wheel and the guide apparatus.

A submersible multistage centrifugal pump contains a set of stages assembled in a cylindrical housing 1. The stage consists of an impeller 2 and a stationary guide device 3. The impeller 2 has a hub 4 and vanes 5. Between the vanes 5 channels 6 of the flowing part of the impeller 2 are formed. 3 has a sleeve 7, an upper disk 8, a lower disk 9 and blades 10 located between the disks 8 and 9. Thus, channels 11 of the flow part of the guide apparatus 3 are formed between the blades 10. At the entrance of the guide apparatus 3 and there is an input annular chamber 12. At the output of the guide apparatus 3, an output annular chamber 13 is made. The annular chambers 12 and 13 provide hydraulic communication of the flowing parts of the impeller 2 and the guide apparatus 3, namely, provide hydraulic communication of channels 6 with channels 11, From the outside axial bearings 15 are made of the guide apparatus 3, providing a space for rotation of the wheel 2. Axial bearings 15 are installed between the horizontal contacting surfaces of the impeller 2 and the guide apparatus 3. the th support is made in the form of a centering bearing 16 mounted on the shaft 17 and placed in the bore of the sleeve 7.

The blades 5 of the impeller 2 have elongated inlet sections 18 located around the circumference with the formation of an axial circular lattice.

The elongation of the blades 5 is made in the direction of the axis of rotation of the impeller 2, to the hub 4.

At the output of the impeller 2, the ends of the blades 5, as in known pumps, can be straight, bent back, or bent forward in the direction of rotation. As in the known pumps, the blades 5 can be located at a right or acute angle to a plane perpendicular to the axis of rotation of the impeller.

In the embodiment depicted in figure 3, in the upper disk 8 of the guide apparatus 3, through holes 19 are made, communicating channels 11 of the flowing part of the guide apparatus 3 with channels 6 of the flowing part of the impeller 2 of the adjacent stage installed above.

In the embodiment depicted in figure 4, in the lower disk 9 of the guide apparatus 3, through holes 20 are made, communicating the channels 11 of the flowing part of the guide apparatus 3 with the channels 6 of the flowing part of the impeller 2 installed below.

In the embodiment depicted in figure 5, in the upper disk 8, in the thick-walled blades 10 and in the lower disk 9 of the guide apparatus 3, through holes 21 are made providing direct communication of the flowing part of the impeller 2 of one stage with the flowing part of the impeller of an adjacent stage.

The shape, size and position of the holes 19, 20 and 21 are selected from the condition of the possibility of overlapping these holes with the blades 5 of the impeller 2. The cross-sectional area of the holes 19, 20 and 21 can act as a regulatory parameter. The upper disk 8 with the simplest geometric shapes can be used as a replacement part. Having a set of upper disks 8 with different areas of holes 19, you can

adjust and adjust the dispersion system when assembling the pump, taking into account the operating conditions of the pump.

The stage of a submersible multistage centrifugal pump operates as follows.

When the shaft 17 rotates, the blades 5 of the impeller 2 exert a force on the pumped medium (liquid or liquid-gas mixture) filling the channels 6 and the flow part of the impeller 2 as a whole. The pumped medium is thus drawn into the rotational motion. The resulting centrifugal forces provide an increase in pressure on the periphery of the impeller 2 and provide a flow in the direction from the center of the impeller 2 to its periphery. The pumped medium is displaced from the channels 6 into the inlet annular chamber 12 of the guide apparatus 3. From the inlet annular chamber 12, the pumped medium enters the channels 11 between the blades 10, where due to the gradual increase in the cross-sectional area of the channels 11 in the direction of flow, the flow velocity is reduced and, accordingly, provides an increase in hydrostatic pressure. From the channels 11, the pumped medium enters the output annular chamber 13, where an axial flow is observed directed along the axis of rotation of the shaft 17. Due to the profile of the blades 10 in the output annular chamber 13, flow swirling in the direction of rotation of the shaft 17 can also take place. Flow with axial direction the flow from the output annular chamber 13 enters the channels of the axial circular lattice formed by the inlet sections 18 on the blades 5 of the next impeller. Inside the aforementioned circular lattice between the inlet sections 18, the flow turns from the axial direction to the radial direction of the flow. The velocity vectors of individual points on the surface of the input sections 18 do not coincide with the motion vectors

individual small portions of the pumped medium, which will inevitably lead to the creation of turbulence in the flow and to the mixing of the pumped medium. The interaction of the elongated inlet sections 18 with the flow of the pumped medium contributes to the preliminary mixing of the gas with the liquid during the pumping of the liquid-gas mixture, which is most typical for oil production conditions, where gas is always present. It is known that mixing, the so-called dispersion, helps to improve the characteristics of the pump during the pumping of liquid-gas mixtures. In the claimed technical solution, the dispersion occurs at the entrance to the impeller 2. In the presented technical solution, the open impeller 2 is used. When the impeller 2 rotates, the blades 5 periodically overlap the openings 19 (20 or 21). The overlap can be full or partial, depending on the ratio of the thickness of the blade 5 with the size of the dispersing hole 19 (20, 21). Due to such cyclical overlapping of these dispersing holes, a pulsed flow of the liquid-gas mixture is realized in them. In this case, not only the flow velocity, but also the flow direction changes with pulses, since with each pulse a stream (return flow) flows around the moving blade 5 and is reflected from it in different directions, depending on the position of the blade 5 relative to the hole 19 (or 20, 21 ) The pulsed nature of the flow through the dispersing holes 19, 20, 21 contributes to the intensification of mixing of the liquid and gas, and, therefore, it is possible to reduce the volumetric flow rate in the return flow. A decrease in the flow rate in the return flow helps to reduce the cost of power for the dispersion process, thereby increasing the efficiency of the pump as a whole. When assembling the pump, you can use one of three types of dispersing holes: 19, or 20, or 21. But you can also

use any combination of such holes, including the simultaneous use of all three types of holes in the same pump stage design.

The upper disk 8 of the guide apparatus 3 can be made removable. This technical solution allows to simplify and reduce the cost of manufacturing technology of the guide apparatus 3.

The axial support 15 can be made in the form of a set of antifriction washers, or by applying antifriction material to contacting surfaces. The axial support 15, the centering bearing 16, the sleeve 7, the lower disk 9, the thick-walled blades 10 and the ring 14 of the guide apparatus 3 provide the transmission of power loads to the housing 1.

Improving the dispersion efficiency is achieved by organizing the pulsed flow of the pumped medium through the dispersing holes 19, 20 or 21. Adjusting the dispersion system can be carried out by changing the total cross-sectional area of the dispersing holes. Such adjustments can be made through the use of removable upper disks 8, each of which may differ in the number of holes and the total area of these holes.

Effective dispersion (crushing of gas bubbles in a liquid) allows you to reduce the number of dispersing stages required for the smooth operation of the pump. This increases the efficiency and reliability of the pump.

Claims (4)

1. The step of a submersible multistage centrifugal pump, consisting of an open impeller, having a hub and vanes, a guide apparatus, an upper disk and a lower disk with vanes located between the disks forming the flow part of the guide apparatus, at the input and output of the flow part of the guide apparatus respectively, the input and output annular chambers, which provide hydraulic communication of the flowing parts of the impeller and the guide apparatus, the impeller vanes Inlet elongated to the hub, circumferentially arranged to form an axial circular grid, axial bearings are installed between the horizontal contacting surfaces of the impeller and the guide apparatus, characterized in that through holes are made through holes communicating the flow part of the impeller with the flow part of the guide apparatus or with the flowing part of the impeller of an adjacent stage, with the possibility of periodic overlapping of these holes with the impeller blades when it rotation. 2. The stage according to claim 1, characterized in that through holes are made in the upper disk of the guide vane, communicating the flowing part of the guide vane of one stage with the flowing part of the impeller of the next stage installed above. 3. The stage according to claim 1, characterized in that through holes are made in the lower disk of the guide apparatus, communicating the flowing part of the guide apparatus with the flowing part of the impeller. 4. The stage according to claim 1, characterized in that the guide apparatus has through holes passing through the upper disc, through the vanes of the guide apparatus and the lower disc, providing direct communication of the flowing part of the impeller of one stage with the flowing part of the impeller of the next stage.