RU2692941C1 - Centrifugal pump impeller for gas-liquid media - Google Patents

Abstract

FIELD: pumps.

SUBSTANCE: invention relates to a centrifugal pump for pumping gas-liquid mixtures with high content of gas phase in a wide range of values and can be used in industry, agriculture and domestic needs. Impeller of the centrifugal pump for gas-liquid media includes main and auxiliary blades. Blades setting angle, formed between tangents, carried out through outlet sections of blades and outer circumference of impeller, is in range from 35° up to 90°. Shape of blades is described by surfaces of the second order, providing possibility of inclination of blades in direction of rotation of impeller and their drawing to input of impeller.

EFFECT: invention is aimed at increasing the created head while maintaining the efficiency of impeller of the centrifugal pump for gas-liquid media.

11 cl, 6 dwg

Description

The invention relates to the field of devices designed for pumping liquids containing gas phase (gas-liquid mixtures), as well as for other media with a high content of the gas phase in a wide range of values, and can be used in industry, agriculture and for domestic needs.

A centrifugal pump impeller is known, containing blades having a curvature in one plane [CN 2204344, publication date: 02.08.1995, IPC: F04D 07/04].

Known impeller centrifugal pump containing blades, curved in one plane [CN 205779755, publication date: 07.12.2016, IPC: F04D 13/06].

As a prototype, an impeller of a centrifugal pump for gas-liquid media was selected, containing main and auxiliary vanes curved in one plane [SU 1359498, publication date: 11.02.2015, IPC: F04D 31/00].

The disadvantage of the prototype is that when pumping gas-liquid mixture, the medium at the exit of the impeller moves at low speed, due to the fact that the angle of the blades formed between the tangents through the output sections of the blades and the outer circumference of the impeller, has a small size, as a result of which at the impeller inlet in its central part, as well as on the back of the blades in the areas of reduced pressure, stagnant zones are formed, leading to the formation of gas bubbles that impede the movement multiphase environment through the flow part of the impeller. The increase in this angle causes hydrodynamic losses, and can also disrupt the continuity of the environment, which reduces the efficiency of the impeller, or leads to its complete inoperability, which ultimately greatly reduces the performance characteristics of a centrifugal pump for gas-liquid environments.

The technical problem that the invention is intended to solve is an increase in the operational characteristics of a centrifugal pump for gas-liquid media.

The technical result achieved by the invention is to increase the generated head while maintaining the efficiency of the impeller of the centrifugal pump for gas-liquid environments.

The invention consists in the following.

The impeller of a centrifugal pump for gas-liquid environments contains the main and auxiliary vanes. Unlike the prototype, the blade installation angle formed between the tangents drawn through the output sections of the blades and the outer circumference of the impeller is in the range from 35 ° to 90 °, and the shape of the blades is described by second-order surfaces that allow the blades to tilt in the direction of rotation of the impeller and pulling them to the impeller inlet.

The impeller of the centrifugal pump can be made by casting or welded-sharpened method and may have a flat or concave shape. The impeller consists of main and top disks and blades. The impeller has an entrance in the central part and an outlet located along the side (end) surface. The impeller has radial working channels formed between the blades, passing from the entrance to the impeller to the exit from it. The blades are designed to create centrifugal force and convert the mechanical energy of the impeller into the hydrodynamic energy of a gas-liquid medium. In this case, the blades have input and output sections.

The output areas of the blades provide the possibility of ejection of the medium from the radial working channels. Output sections are located at the exit of the impeller. The angle of installation of the blades formed between the tangents drawn through the output sections of the blades and the outer circumference of the impeller is in the range from 35 ° to 90 °, which provides an increase in the absolute velocity at the ends of the blades. When the angle is less than 35 °, the generated head does not increase, and if the angle is more than 90 °, an excessive increase in hydraulic resistance, reduced operating efficiency and increased wear of the impeller may occur. To maximize the generated head, the angle of the blades formed between the tangents drawn through the output sections of the blades and the outer circumference of the impeller may be in the range from 80 ° to 90 °.

The shape of the blades is described by second-order surfaces, that is, any section of the blade in any plane has a curvature, which makes it possible to incline the blades in the direction of rotation of the impeller and the possibility of their maximum drawing to the impeller inlet. The surface of the second order can be profiled by calculating the velocity triangles in a variety of sections taking into account the selected values of the installation angles of the blades formed between the tangents held through the output and input sections of the blades and tangent to the outer circumference of the impeller.

Additionally, to reduce hydrodynamic resistance and increase the efficiency of the impeller, the inlet section of the blades can be located as close as possible to the impeller inlet, and the angle between the tangent to the inlet section of the blade and the tangent to the outer circumference of the impeller can be in the range from 10 ° to 25 ° .

To maximize the reduction of hydrodynamic resistance and increase the head, while maintaining the efficiency of the impeller, the angle of the blades formed between the tangents drawn through the inlets and the outer circumference of the impeller can be in the range from 12 ° to 15 °, and the angle of the blades formed between the tangents drawn through the output sections of the blades and the outer circumference of the impeller may be in the range from 80 ° to 90 °.

Additionally, to increase the head and improve the cavitation characteristics of the impeller, it can add an additional row of auxiliary vanes, the shape of which can repeat the shape of the main vanes. The output sections of the auxiliary blades of the additional row, relative to the output sections of the main blades, can be located at the same distance from the axis of rotation of the impeller. Auxiliary blades of an additional row may have a length of from 40% to 60% of the length of the main blades, which ensures their minimal hydrodynamic resistance to the flow of the medium. The angle between the tangent to the inlet section of the blade and the tangent to the outer circumference of the impeller can be in the range from 35 ° to 90 °, which also provides an increase in pressure. Also, the use of an additional row of auxiliary blades allows to improve the weight and size characteristics of the impeller by reducing the number and thickness of the main blades and makes it possible to manufacture the impeller from polymeric and composite-polymeric materials.

Additionally, to increase the generated head while maintaining the efficiency of the impeller, the auxiliary vanes can be positioned relative to the main vanes with an offset of 1/12 - 1/20 of the sector angular size.

Additionally, to reduce the risk of turbulent turbulence behind the output edge of the blades and increase the generated head while maintaining the efficiency of the impeller, the blades may have a narrowing from the middle to the output edge, while the thickness of the output edge can be up to 25% of the width of the middle of the blades.

Additionally, to reduce drag and increase the generated head while maintaining the efficiency of the impeller, the blades may have a narrowing from the middle to the input edge, while the thickness of the input edge can be up to 25% of the width of the middle of the blades.

The invention has previously unknown to the prior art set of essential features, characterized in that:

- the installation angle of the blades, formed between the tangents drawn through the output sections of the blades and the outer circumference of the impeller, is in the range from 35 ° to 90 °, which provides an increase in the absolute velocity at the exit of the impeller and leads to an increase in the dynamic component of the pressure created by the worker wheel.

- the shape of the blades is described by second-order surfaces that allow the blades to tilt in the direction of rotation of the impeller and pull them towards the impeller inlet, which makes it possible to place the inlet section of the blade as close as possible to the impeller entrance to eliminate the risk of formation of stagnant zones and reduce surface hydrodynamic resistance blades and improve the cavitation characteristics of the impeller, leading to increased continuity of the environment

Thus, the combination of distinctive features provides an increase in the dynamic component of the head, reduces the hydrodynamic resistance, the risk of formation of stagnant zones at the inlet in the central part, as well as on the back side of the blades in areas of reduced pressure and improves the cavitation characteristics of the impeller, allowing you to achieve the technical result increase the generated head while maintaining the efficiency of the impeller.

The invention can be made from known materials using known means.

The invention is illustrated by the following drawings.

FIG. 1 - Diagrammatic representation of the impeller of a centrifugal pump for gas-liquid media with indication of the angle of installation of the blades formed between the tangents drawn through the inlet and outlet sections of the blades and the outer circumference of the impeller, top view.

FIG. 2 - Impeller of a centrifugal pump for gas-liquid environments, left view, longitudinal section.

FIG. 3 - The impeller of a centrifugal pump for gas-liquid environments, top view, cross-section.

FIG. 4 - Impeller of a centrifugal pump for gas-liquid environments, three-dimensional model, axonometric view.

FIG. 5 - Impeller of a centrifugal pump for gas-liquid environments, three-dimensional model, left view.

FIG. 6 - Paddle impeller of a centrifugal pump for gas-liquid environments, having the form described by second-order surfaces, a general view.

The centrifugal pump for gas-liquid environments contains an impeller that has an input and an output and consists of a main disk 1, a covering disk 2 and blades 3 with a shape described by second-order surfaces that allow the blades to tilt in the direction of rotation of the impeller and pull them to the worker’s inlet wheels. The angle β ₁ installation blades 3 formed between the tangents drawn through the output sections of the blades 3 and the outer circumference of the impeller is 90 °, and the angle β ₂ installation blades 3 formed between the tangents drawn through the input sections of the blades 3 and external impeller circumference equal to 12 °.

The invention works as follows.

The centrifugal pump is immersed in a gas-liquid medium, and the impeller begins to rotate. The gas-liquid medium enters the impeller inlet and, with minimal hydrodynamic resistance, bending around the inlet areas of the blades 3, set at an angle β ₂ , moves along the surfaces of the second order of the blades 3, interacting with the exit parts of the blades 3, set at an angle β ₁ and, acquiring maximum absolute speed, coming out of the impeller of the centrifugal pump, reducing the risk of formation of stagnant zones at the impeller inlet and contributing to the grinding of gas phase bubbles. In this case, it is possible to reduce the risk of formation of stagnant zones and disruption of continuity of the medium at the impeller inlet in a wide range of gas phase content in a liquid, allowing in some cases to achieve an increase in efficiency. Thus, a technical result is achieved, which consists in increasing the generated head while maintaining the efficiency of the impeller and increases the performance characteristics of a centrifugal pump for gas-liquid media.

Claims (11)

1. The impeller of a centrifugal pump for gas-liquid environments, containing the main and auxiliary blades, characterized in that the angle of the blades formed between the tangents drawn through the output sections of the blades and the outer circumference of the impeller is in the range from 35 ° to 90 °, and the shape of the blades is described by second-order surfaces that allow the blades to tilt in the direction of rotation of the impeller and pull them towards the impeller inlet. 2. The impeller of the centrifugal pump under item 1, characterized in that the angle of installation of the blades formed between the tangents, conducted through the output sections of the blades and the outer circumference of the impeller is in the range from 80 ° to 90 °. 3. The impeller of the centrifugal pump under item 1, characterized in that the angle of installation of the blades formed between the tangents drawn through the inlet portions of the blades and the outer circumference of the impeller is in the range from 10 ° to 25 °. 4. The impeller of a centrifugal pump according to claim 3, characterized in that the angle of installation of the blades formed between the tangents drawn through the inlet portions of the blades and the outer circumference of the impeller is in the range from 12 ° to 15 °, and the angle of installation of the blades formed between the tangents drawn through the exit portions of the blades and the outer circumference of the impeller is in the range from 80 ° to 90 °. 5. The impeller of the centrifugal pump under item 1, characterized in that the auxiliary vanes have a length of from 40% to 60% of the length of the main blades. 6. The impeller of a centrifugal pump according to claim 5, characterized in that the angle of installation of the blades formed between the tangents drawn through the output sections of the auxiliary vanes and the outer circumference of the impeller is in the range from 35 ° to 90 °. 7. The impeller of the centrifugal pump under item 5, characterized in that it contains an additional row of auxiliary vanes. 8. The impeller of the centrifugal pump according to claim 7, characterized in that the auxiliary vanes of the additional row have a length of from 40% to 60% of the length of the auxiliary vanes. 9. The impeller of the centrifugal pump under item 1, characterized in that the auxiliary blades are located relative to the main blades with an offset of 1/12 - 1/20 of the angular size of the sector. 10. The impeller of the centrifugal pump under item 1, characterized in that the blades have a narrowing from the middle to the output edge, while the thickness of the output edge is up to 25% of the width of the middle of the blades. 11. The impeller of the centrifugal pump under item 1, characterized in that the blades have a narrowing from the middle to the input edge, while the thickness of the input edge is up to 25% of the width of the middle of the blades.

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