RU73412U1 - SUBMERSIBLE MULTI-STAGE PUMP - Google Patents

Abstract

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. The technical result consists in increasing the efficiency and reliability of the pump by improving the quality of the surfaces of the flow part of the pump and through the use of wear-resistant materials and coatings. The specified technical result is achieved in that the step of the submersible multistage centrifugal pump consists of a guide apparatus, at the inlet and outlet of the flowing part of the guide apparatus, respectively, inlet and outlet annular chambers are made, which provide hydraulic communication of the flowing parts of the impeller and the guide apparatus, the impeller having a hub and vanes, the inlet portions of which have protrusions located in the outlet annular chamber of the guide apparatus with the formation of an axis second circular array. Moreover, the protrusions of the inlet sections of the blades are made on a sleeve fixed in the bore of the impeller. The input sections of the blades made on the sleeve are located at an angle “A” to the plane coinciding with the end of the impeller. The angle "A" lies in the range from 20 ° to 90 °. The number of protrusions of the input sections of the blades made on the sleeve is less than the number of blades on the wheel.

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.

Known step submersible multistage centrifugal pump, consisting of an impeller having a hub and vanes, and a 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 flow 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 impeller can be designed as an open type wheel and is equipped with blades mounted directly on the hub. [Sazonov Yu.A., Zayakin V.I. Utility Model Patent No. 59752. IPC F04D 13/10. Stage submersible multistage centrifugal pump. Application No. 2006124211/22 dated 05.07.2006. Publ. BI No. 36, 12/27/2006].

A disadvantage of the known device is its low manufacturability and limited ability to use modern materials and processing technologies. Modern technological capabilities of mechanical engineering are able to increase the reliability and efficiency of the pump as a whole, by improving the quality of the surfaces of the flow part of the pump and by using wear-resistant materials and coatings.

The technical result of using the utility model is to increase the efficiency and the reliability of the stage of a submersible multistage centrifugal pump, by improving the quality of the surfaces of the flowing part of the pump and by using wear-resistant materials and coatings. In addition, the new technical solution should simplify and reduce the cost of manufacturing technology for parts of the impeller and the most submersible multistage centrifugal pump.

The specified technical result is achieved in that the step of the submersible multistage centrifugal pump consists of a guide apparatus, at the inlet and outlet of the flowing part of the guide apparatus, respectively, inlet and outlet annular chambers are made, which provide hydraulic communication of the flowing parts of the impeller and the guide apparatus, the impeller having a hub and vanes, the inlet portions of which have protrusions located in the outlet annular chamber of the guide apparatus with the formation of an axis second circular array. Moreover, the protrusions of the inlet sections of the blades are made on a sleeve fixed in the bore of the impeller. The input sections of the blades made on the sleeve are located at an angle “A” to the plane coinciding with the end of the impeller. The angle "A" lies in the range from 20 ° to 90 °. The number of protrusions of the input sections of the blades made on the sleeve is less than the number of blades on the wheel.

The design of the inventive step submersible multistage centrifugal pump opens up the possibility of using new and diverse materials in the manufacture of pumps. The impeller and sleeve with the input sections of the blades can be made of dissimilar materials. For example, impeller with centrifugal

the blades are made of metal, and the sleeve with the inlet portions of the blades, as a embedded part, is made of plastic or ceramic material, for example, from a hard alloy. It is possible that all surfaces of the flowing part of the impeller and the sleeve with the inlet sections of the blades have a protective wear-resistant coating.

It is possible to use the sleeve with the input sections of the blades as a regulatory element. Then, when replacing the sleeve with another, with a different geometry of the input vanes, you can change the characteristics of the pump as a whole, thereby expanding the range of regulation of the pump. In this case, the impeller is made collapsible, with the possibility of replacing the sleeve with the input sections of the blades.

The location of the input sections of the blades made on the sleeve at an angle "A" to the plane coinciding with the end of the impeller, reduce the energy loss of the flow at the entrance to the impeller. The minimum value of the angle “A” at 20 ° is determined by the overlapping of the inlet sections of the edges of the flowing part of the impeller. The maximum value of the angle “A” at 90 ° is used when it is necessary to pump liquids with a high gas content. The dispersion of the mixture improves.

Reducing the number of protrusions of the input sections of the blades made on the sleeve, relative to the number of blades on the wheel, allows to increase the flow area of the axial circular grating, and thus reduce the energy loss of the flow at the entrance to the impeller.

The claimed technical solution allows the use in the manufacture of pumps high-performance technologies, for example,

such as cutting materials using a laser or using a water jet.

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 by improving the quality of the surfaces of the flow part of the pump and through the use of wear-resistant materials and coatings.

The claimed technical solution provides a simplification of the manufacture of a submersible multistage centrifugal pump stage, in the presence of new pump control capabilities.

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 pump stages of a submersible multistage centrifugal pump.

The figure 2 shows the stage of a submersible multistage centrifugal pump separately (isometry). For clarity, a quarter of the guide assembly is cut out in the image.

The figure 3 shows the impeller and the sleeve with the input sections of the blades. The angle “A” is shown between the input sections of the blades made on the sleeve and the plane coinciding with the end of the impeller. For clarity, a quarter of the impeller and sleeve are cut out on the image.

The figure 4 shows the impeller and the sleeve with the input sections of the blades in isometry.

The device and principle of operation of the inventive stage submersible multistage centrifugal pump are presented on the example of its use.

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 fixed guide vane 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 hub 7, an upper disk 8, a lower disk 9 and vanes 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 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 the channels 6 with the channels 11. The ring housing 14 axial bearings 15 are provided between the contacting horizontal surfaces of the impeller 2 and the directing device 3. Axial bearings 15. Radial support is made centering a bearing 16 mounted on the shaft 17.

In the annular bore made in the hub 4 of the impeller 2, a sleeve 18 is placed on which the protrusions of the inlet sections of the blades 19 are made. The curved sections of the protrusions 19 of the sleeve 18 are located at an angle "A" to the plane coinciding with the end of the impeller 2.

In the proposed embodiment, the number of protrusions of the input sections of the blades 19 at the sleeve 18 is two times less than the number of blades 5 of the impeller 2.

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 gas-liquid 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. From the channels 6, the pumped medium is displaced into the inlet annular chamber 12 of the guide apparatus 3. From the inlet ring 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 input of the sleeve 18 of the next stage. The curved portion of the protrusions of the inlet portions of the blades 19 provides an unobtrusive flow inlet into the channels between the protrusions 19. Next, the flow is drawn into the rotational movement and enters the channels 6 between the blades 5. The process is repeated in each subsequent stage of the pump.

To transmit torque to the protrusions of the input sections of the blades 19 of the sleeve 18, you can use well-known technical

solutions. For example, keyway or splined connection. For the non-separable design of the wheel 2, some types of welding materials can be used.

Axial support 15, the centering bearing 16, the hub 7, the upper disk 8, the housing 14 of the guide apparatus 3 provide the transmission of power loads to the housing 1.

It is possible to use the sleeve 18 as a regulating element and a replaceable part. Then, when replacing such a replacement part with another, with a different geometry of the protrusions of the inlet sections of the blades 19, it is possible to change the characteristics of the pump as a whole, thereby expanding the range of pump control. In this case, the impeller 2 is made collapsible, with the possibility of replacing the sleeve 18.

The design of the inventive stage submersible multistage centrifugal pump opens up the possibility of using new and diverse materials in the manufacture of the impeller 2. Centrifugal blades 5 and the sleeve 18 with the protrusions of the inlet sections of the blades 19 can be made of dissimilar materials. For example, the blades 5 are made of metal, and the sleeve 18 with the protrusions 19 is made of plastic. Or, the blades 5 are made of metal with a protective wear-resistant coating, and the sleeve 18 with the protrusions 19 is made of ceramic material, for example, of a hard alloy. It is possible that all surfaces of the flowing part of the impeller 2 and the sleeve 18 have a protective wear-resistant coating.

The claimed technical solution allows to simplify the manufacture of a submersible multi-stage pump due to the ability to apply high-production technologies in production, for example, such as cutting materials using a laser or using a water jet.

The claimed technical solution allows, when replacing the sleeve with another, with a different geometry of the protrusions of the input sections of the blades, to change the characteristics of the pump as a whole, thereby expanding the range of regulation of the pump.

The claimed technical solution allows to reduce the loss of energy flow at the entrance to the flowing part of the wheel and to increase the efficiency of the pump.

Claims (4)

1. The step of a submersible multistage pump, consisting of a guide apparatus, inlet and outlet annular chambers, respectively, are provided at the inlet and outlet of the flowing part of the guide apparatus, which provide hydraulic communication between the flowing parts of the impeller and the guide apparatus, the impeller has a hub and vanes, the inlet portions of which have protrusions located in the output annular chamber of the guide apparatus with the formation of an axial circular lattice, characterized in that the protrusions of the input sections l the casing is made on a sleeve fixed in the bore of the impeller. 2. The stage according to claim 1, characterized in that the input sections of the blades made on the sleeve are located at an angle "A" to the plane coinciding with the end of the impeller. 3. The step according to claim 2, characterized in that the angle "A" lies in the range from 20 to 90 °. 4. The stage according to claim 1, characterized in that the number of protrusions of the input sections of the blades made on the sleeve is less than the number of blades on the wheel.