In a variety of environments, such as wellbore environments, pumps are used to produce or otherwise move fluids. For example, multiple stage, centrifugal pumps are used in the production of oil. A centrifugal pump is connected into an electric submersible pumping system located, for example, in a wellbore drilled into an oil-producing formation. The centrifugal pump uses a plurality of stages with each stage having an impeller and a diffuser. The impellers are rotated by a shaft to move the fluid, while the diffusers guide the flowing fluid from one impeller to the next.
The fluid can contain particulate matter, such as sand, having abrasive properties. As the fluid flows through the pump, the particulate matter can abrade pump components, potentially shortening the life of the pump. Certain components, such as impellers and diffusers, are particularly susceptible to abrasion during operation of the pump.
In general, the present invention provides a system and method that facilitates the pumping of fluids, such as fluids found in a subterranean formation. A pump utilizes pump components that are readily formed to enable the improvement of various pumping parameters, such as pumping efficiency. However, the structure of the pump components enables maintenance of high wear resistance for use in abrasive environments.
Certain embodiments of the invention will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements, and:
In the following description, numerous details are set forth to provide an understanding of the present invention. However, it will be understood by those of ordinary skill in the art that the present invention may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible.
The present invention generally relates to a system and method for pumping fluids. The system and method are useful with, for example, a variety of electric submersible pumping systems. However, the devices and methods of the present invention are not limited to use in the specific applications described herein to enhance the understanding of the reader.
Referring generally to
In the embodiment illustrated, system 10 comprises a pump 20 having a pump intake 22. System 10 further comprises a submersible motor 24 and a motor protector 26 disposed between submersible motor 24 and submersible pump 20. System 10 is suspended within wellbore 12 by a deployment system 28. Deployment system 28 may comprise, for example, production tubing, coiled tubing or cable. A power cable 30 is routed along deployment system 28 and electric submersible pumping system 10 to provide power to submersible motor 24.
In the illustrated example, submersible pump 20 is a centrifugal pump having one or more stages 32, as illustrated in
Each stage 32 comprises a diffuser 44 and an impeller 46. Generally, impellers 46 rotate with shaft 40 and may be rotationally affixed to shaft 40 by, for example, a key and keyway. The rotating impellers 46 impart motion to fluid flowing through pump 20 and move the fluid from one stage 32 to the next until the fluid is discharged through flow passages 48 at first end 36. The diffusers 44 are rotationally stationary within outer housing 34 and serve to guide the fluid from one impeller 46 to the next.
As illustrated best in
In the embodiment illustrated in
As illustrated, a plurality of vanes 57 extend radially outward from short hub 54. In this embodiment, vanes 57 also are formed from moldable material 52 and integrally molded with short hub 54. Each of the vanes 57 includes an internal flow passage 58 through which fluid flows in the direction of arrow 60 during operation of pump 20. The fluid is directed through corresponding flow passages of the next sequential diffuser, as explained more fully below.
Each impeller 46 further comprises a sleeve 62, as illustrated best in
In the embodiment illustrated, sleeve 62 is generally circular and has an opening 64 sized to slide over shaft 40, similar to short hub 54. Additionally, each sleeve 62 may have a keyway 66 that cooperates with a key along shaft 40 to prevent rotation of sleeve 62 with respect to the shaft. The wear resistant sleeve 62 provides radial support for the impeller and increases bearing and pump life, especially when pumping fluids with substantial particulate content.
The impeller 46 also may comprise a thrust ring 68 disposed between the impeller 46 and the next adjacent diffuser. The thrust ring is disposed on a side of impeller 46 opposite sleeve 62. Thrust ring 68 may be formed of a metal material or other wear resistant material.
Referring generally to
The illustrated diffuser 44 also comprises a reinforcement member 74 able to reinforce moldable material 72. For example, reinforcement member 74 may comprise a ring 76 disposed circumferentially along a radially outlying region 78 of diffuser 44. Ring 76 comprises a plurality of gripping features 80 that hold ring 76 in place with respect to moldable material 72. For example, gripping features 80 may comprise perforations formed through ring 76, as illustrated. In the embodiment of
Diffuser 44 comprises a hub portion 82 having an axial opening 84 sized to rotatably receive sleeve 62 of the next adjacent impeller 46. A diffuser body portion 86 extends from hub portion 82 to radially outlying region 78. Body portion 86 has a plurality of diffuser flow passages 88 for directing fluid in the direction of arrows 90 as the fluid moves from an upstream impeller to the next sequential downstream impeller. Each diffuser 44 also may comprise a bearing sleeve 92 disposed along the interior of hub portion 82. Bearing sleeve 92 may be formed of a wear resistant material, such as a metal material, e.g. ni-resist or stainless steel. As illustrated, bearing sleeve 92 has a plurality of external gripping features, e.g. protuberances 94 that extend radially outward into the moldable material 72 of hub portion 82. These features secure bearing sleeve 92 within diffuser 44. Bearing sleeve 92 provides a wear resistant material in which sleeve 62 of the next adjacent impeller 46 rotates during operation of pump 20. Bearing sleeve 92 also can serve as a second reinforcement member to structurally reinforce diffuser 44.
The composite diffuser 44 enables, for example, greater accuracy of form and smoothness of surface due to moldable material 72. Simultaneously, reinforcement member 74 provides added strength to resist mechanical loads and pressure loads. It should be noted that reinforcement member 74 may have other configurations or be formed of other materials. For example, the member may be formed of wire mesh or be formed as single or multiple reinforcement components disposed along radially outlying region 78 and/or along body portion 86 or hub portion 82.
Although only a few embodiments of the present invention have been described in detail above, those of ordinary skill in the art will readily appreciate that many modifications are possible without materially departing from the teachings of this invention. Accordingly, such modifications are intended to be included within the scope of this invention as defined in the claims.
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Number | Date | Country |
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61283797 | Dec 1986 | JP |
Number | Date | Country | |
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20050074330 A1 | Apr 2005 | US |