This non-provisional patent application claims priority under 35 U.S.C. §119(a) from Patent Application No. 201510979898.6 filed in The People's Republic of China on Dec. 23, 2015.
The present invention relates to an impeller, and in particular, to a centrifugal impeller and a pump using the impeller.
A centrifugal pump usually includes a motor which drives an impeller to rotate to create a negative pressure inside the pump, such that liquid is continuously drawn in and propelled out. The impeller is an indispensable component of the pump, and its design and construction directly affects the fluid delivery efficiency of the pump.
In a conventional centrifugal pump, the impeller is mounted within a hollow chamber of the volute housing. A large gap usually exists between the impeller and an end wall of the hollow chamber adjacent an inlet. After the fluid enters the hollow chamber via the inlet and is rotated by the impeller, part of the fluid may flow back into the inlet via the gap, which may cause unstable flow velocity of the fluid and hence poor fluid delivery efficiency of the pump.
Thus, there is a desire for an impeller with improved efficiency and a pump using the impeller.
An impeller comprises a back cover plate, a plurality of vanes disposed on the back cover plate, and a hub disposed on the back cover plate. The impeller further comprises a sealing ring, the sealing ring disposed on one end of the impeller away from the back cover plate.
Preferably, the back cover plate defines a recess in one side of the back cover plate, and the hub is disposed in the recess of the back cover plate.
Preferably, the back cover plate further defines a plurality of balance holes.
Preferably, the number of the balance holes is the same as the number of the vanes.
Preferably, the plurality of balance holes is arranged into a ring in the back cover plate, and each of the vanes is disposed between two adjacent balance holes.
Preferably, the back cover plate further defines a plurality of through holes arranged into a ring, and the plurality of through holes are spaced from each other and evenly distributed between the ring cooperatively defined by the balance holes and the hub.
Preferably, each of the balance holes is arc-shaped, and a central axis of the ring cooperatively defined by the balance holes is coincident with a central axis of the back cover plate.
Preferably, the vanes extend from start positions adjacent a central axis of the back cover plate toward an edge of the back cover plate.
Preferably, the back cover plate comprises a connecting plate and a support plate, one side of each of the vanes away from the sealing ring is connected to the connecting plate and the support plate, and the hub is disposed on one side of the support plate away from the vanes.
Preferably, the connecting plate is annular, a cross section of the support plate is annular, and an inner diameter of the connecting plate is greater than an outer diameter of the cross section of the support plate.
Preferably, each of the vanes includes a main portion, one end of the main portion is connected to the sealing ring, and the other end is connected to the connecting plate and the support plate.
Preferably, each of the vanes includes a connecting portion projecting from one end of the main portion, and the connecting portion is connected between the connecting plate and the support plate to divide a spacing between the connecting plate and the support plate into a plurality of balance holes.
Preferably, the support plate defines a plurality of through holes arranged into a ring, and the ring cooperatively defined by the plurality of through holes is concentric with the hub.
A pump comprises a volute housing and a driving device. The volute housing comprises a housing body, an inlet pipe and an outlet pipe. The housing body comprises a diffusor chamber, and the inlet pipe and the outlet pipe are in communication with the diffusor chamber. The driving device is connected to the housing body. The pump further comprises an impeller as described above. The impeller is rotatably received in the housing body and connected to the driving device, and the driving device is configured to drive the impeller to rotate.
Preferably, the pump further comprises a baffle portion disposed on an end wall in the diffusor chamber adjacent the inlet pipe.
Preferably, one end of the baffle portion defines an annular engagement groove therein along a circumferential direction of the end, and the sealing ring is rotatably received in the engagement groove.
In the pump of the present invention, the impeller is provided with the sealing ring, and the volute housing is provided with the engagement groove that receives the sealing ring. This changes the way the fluid flows in the diffusor chamber of the volute housing and increases the resistance to the fluid flowing back into the inlet pipe, thereby further optimizing the design of the volute housing and resulting in enhanced fluid delivery efficiency. In addition, the back cover plate of the impeller is provided with the plurality of arc strip-shaped balance holes, which reduces the axial force applied to the impeller and results in more stable rotation of the impeller.
Below, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
The technical solutions of the embodiments of the present invention will be clearly and completely described as follows with reference to the accompanying drawings. Apparently, the embodiments as described below are merely part of, rather than all, embodiments of the present invention. Based on the embodiments of the present disclosure, any other embodiment obtained by a person skilled in the art without paying any creative effort shall fall within the protection scope of the present invention.
It is noted that, when a component is described to be “fixed” to another component, it can be directly fixed to the another component or there may be an intermediate component. When a component is described to be “connected” to another component, it can be directly connected to the another component or there may be an intermediate component. When a component is described to be “disposed” on another component, it can be directly disposed on the another component or there may be an intermediate component. The directional phraseologies such as “perpendicular” or similar expressions are for the purposes of illustration only.
Unless otherwise specified, all technical and scientific terms have the ordinary meaning as understood by people skilled in the art. The terms used in this disclosure are illustrative rather than limiting.
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The volute housing 20 includes a housing body 23, an inlet pipe 24, and outlet pipe 26 (see
The housing body 23 includes a diffusor chamber 232 with an open end. The open end of the diffusor chamber 232 is connected to the driving device 30. The diffusor chamber 232 allows the impeller 50 to be rotatably received therein.
In this embodiment, the inlet pipe 24 is substantially hollow tubular, which is disposed on one side of the housing body 23 away from the open end of the diffusor chamber 232, with a central axis of the inlet pipe 24 substantially parallel to or coincident with a central axis of the diffusor chamber 232. The inlet pipe 24 defines a flow passage 241 along its central axis. The flow passage 241 communicates with the diffusor chamber 232.
In this embodiment, the baffle portion 25 is generally an annular projection which projects from an end wall (not labeled) in the diffusor chamber 232 adjacent the inlet pipe 24. Preferably, a central axis of the baffle portion 25 is coincident with the central axis of the inlet pipe 24. An annular engagement groove 251 is formed in and along a circumferential direction of one end of the baffle portion 25 away from the inlet pipe 24. The engagement groove 251 is used to receive the impeller 50.
The outlet pipe 26 is disposed on the housing body 23. The outlet pipe 26 is in fluid communication with the diffusor chamber 232, such that the inlet pipe 24, the diffusor chamber 232, and the outlet pipe 26 collectively form a channel for flowing of the fluid such as water, oil or gas. When the driving device 30 drives the impeller 50 to rotate, the fluid can enter the diffusor chamber 232 via the inlet pipe 24 and be discharged out of the diffusor chamber 232 via the outlet pipe 26.
In this embodiment, the pump 100 is preferably a unidirectional rotary pump, and the driving device 30 is preferably powered by a unidirectional rotary motor. The driving device 30 includes a support member 31 for mounting of the rotary motor and being connected to the volute housing 20, and a driving shaft 32. The driving device 30 drives the impeller 50 to rotate through the driving shaft 32. In particular, one end of the driving shaft 32 extends into the diffusor chamber 232 of the volute housing 23 and is connected to the impeller 50 such that the impeller 50 can be rotated synchronously with the driving shaft 32.
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In this embodiment, the back cover plate 52 is substantially circular disc-shaped, a center of which is recessed toward one side to form a recess 521 at the the center area of the back cover plate 52. The recess 521 is used to receive the hub 56 such that an axial size of the impeller 50 is reduced, which facilitates miniaturization of the impeller 50. The back cover plate 52 further defines balance holes. In this embodiment, the balance holes 525 are through holes passing through the back cover plate 52, and the number of the balance holes 521 is the same as the number of the vanes 53. In this embodiment, each of the balance holes 525 is arc strip-shaped, and the arcs of all the balance holes 525 collectively form a circle concentric with the hub 56. The balance holes 525 of the back cover plate 52 can balance the flow pressure on opposite sides of the back cover plate 52, reduce the axial force applied on the impeller 50, maintain rotation stability of the impeller 50, and can thus reduce the operational vibration of the pump 100 and ensure the operation efficiency of the pump 100.
In this embodiment, the number of the balance holes 525 and the number of the vanes 535 are both five. The balance holes 525 are arranged into a ring in the back cover plate 52. In addition, each balance hole 525 is substantially arc-shaped, and one end of each vane 53 is disposed between two adjacent balance holes 525. A central axis of the ring cooperatively defined by the balance holes 525 is coincident with the central axis of the back cover plate 52.
The vanes 53 are uniformly distributed on one side of the back cover plate 52 and extend from start positions adjacent the central axis of the back cover plate 52. In this embodiment, the vanes 53 are curved vanes, which radiate curvedly from the start positions adjacent the central axis of the back cover plate 52 toward an edge of the back cover plate 52 and terminating at the edge of the back cover plate 52. Each vane 53 is perpendicular to the back cover plate 52.
In this embodiment, the sealing ring 55 is an annular structure. One side of the sealing ring 55 is connected to one side of the vanes 53 away from the back cover plate 52, and the other side of the sealing ring 55 is rotatably received in the engagement groove 251. The hub 56 is disposed on one side of the back cover plate 52 away from the impeller 53. The hub 56 is fixedly attached around on one end of the driving shaft 32, or movably connected with one end of the driving shaft 32 in a spline-connection manner such that the impeller 50 can be rotated synchronously with the driving shaft 32.
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Each vane 53 includes a main portion 531 and a connecting portion 532. One end of the main portion 531 is connected to the sealing ring 55, and the other end is connected to the connecting plate 522 and support plate 524 of the back cover plate 52. In this embodiment, a generally central area of one end of the main portion 531 away from the sealing ring 55 protrudes to form the connecting portion 532. The connecting portion 532 is connected between the connecting plate 522 and the support plate 524 of the back cover plate 52 to divide a spacing (not labeled) between the connecting plate 522 and the support plate 524 into the plurality of the balance holes 525.
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It should be understood that the vanes 50 of the present invention may be integrally formed, or alternatively, one or some of the back cover plate 52, vanes 53, sealing ring 55 and hub 56 may be separately formed and then assembled through welding, gluing or mortise-tenon connection.
In the pump 100 of the present invention, the impeller 50 is provided with the sealing ring 55, and the volute housing 20 is provided with the engagement groove 251 that receives the sealing ring 55. This changes the way the fluid flows in the diffusor chamber 232 of the volute housing 20 and increases the resistance to the fluid flowing back into the inlet pipe 24, thereby further optimizing the design of the volute housing 20 and resulting in enhanced fluid delivery efficiency. In addition, the back cover plate 52 of the impeller 50 is provided with the plurality of arc strip-shaped balance holes 525, which reduces the axial force applied to the impeller 50 and results in more stable rotation of the impeller 50.
Although the invention is described with reference to one or more embodiments, the above description of the embodiments is used only to enable people skilled in the art to practice or use the invention. It should be appreciated by those skilled in the art that various modifications are possible without departing from the spirit or scope of the present invention. The embodiments illustrated herein should not be interpreted as limits to the present invention, and the scope of the invention is to be determined by reference to the claims that follow.
Number | Date | Country | Kind |
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2015 1097 9898.6 | Dec 2015 | CN | national |