Patent Application
20130320148
The present invention generally relates to an impeller for a centrifugal pump, a centrifugal pump including the impeller, and an aircraft fuel system including the centrifugal pump. In particular, the present invention relates to an impeller that maximizes centrifugal pump efficiency, particularly in the presence of fluid input having a vaporized fluid and liquid fluid, a centrifugal pump including the impeller, and an aircraft fuel system including the centrifugal pump.
Typical gas turbine engine fuel supply systems include a fuel source, such as a fuel tank, and one or more pumps that draw fuel from the fuel tank and deliver pressurized fuel to the fuel manifolds and fuel nozzles in the engine combustor via a main supply line. These pumps may include an aircraft or tank level pump, a boost pump, and a high pressure pump. The boost pump is typically a centrifugal pump and the high pressure pump is typically a gear pump, though in some applications the high pressure pump may also be a centrifugal pump.
Centrifugal pumps generally include a pump housing with a fluid inlet into the pump housing. An impeller is rotatably disposed in the pump housing for pressurizing the fluid, and the impeller is typically driven by an engine gear box. The impeller rotates at high speeds to draw the fluid in and to pressurize the fluid. The pressurized fluid is directed to a pump outlet. In the aircraft fuel systems, the pressurized fluid is fuel and the pressurized fuel is provided from the centrifugal pump to either the high pressure pump and/or to the main supply line.
There is a general desire to maximize pressure in the pressurized fuel, or to maximize the efficiency of the centrifugal pumps in pressurizing the fuel in aircraft fuel systems. Under certain operating conditions, such as at low atmospheric pressures associated with high altitudes at which gas turbine engines in aircraft operate, the centrifugal pumps may operate at low fuel inlet pressures. At the low fuel inlet pressures, a high amount of vaporized fuel may be present with liquid fuel at the fuel inlet and may result in inefficient pressurization of the fuel. As a result, insufficient pressures may be realized in the pressurized fuel based upon the high amount of vaporized fuel at the fuel inlet, or pressurization may be inefficient.
While efforts have been made to separate vaporized fuel from liquid fuel at the fuel inlet of centrifugal pumps in gas turbine engines, such efforts often result in loss of the vaporized fuel or routing of the vaporized fuel out of the centrifugal pump, thereby requiring auxiliary mechanisms for handling the vaporized fuel.
Accordingly, it is desirable to provide a centrifugal pump that maximizes efficiency in pressurizing fuel, or any liquid that is to be pressurized by the centrifugal pump, under conditions at which low pressures result in a high amount of vaporized fluid being present in the fluid inlet to the centrifugal pump. It is also desirable to provide a centrifugal pump that maximizes efficiency in pressurizing liquid without requiring routing of the vaporized fluid out of the centrifugal pump. Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.
An impeller for a centrifugal pump, a centrifugal pump including the impeller, and an aircraft fuel system including the centrifugal pump are provided herein. In an embodiment, the impeller includes a central hub that is disposed along a rotational axis of the impeller and that defines an axial bore that extends through at least a portion of the central hub along the rotational axis. The central hub further defines an opening to the axial bore at a leading end of the central hub. The impeller further includes an impeller section that includes at least one impeller vane fixed to the central hub. The impeller section is spaced from the leading end of the central hub. The impeller further includes an inducer section that is disposed between the leading end of the central hub and the impeller section. The inducer section includes at least one inducer vane that extends along an outer surface of the central hub. The central hub defines at least one radial aperture in the inducer section. The at least one radial aperture is in fluid communication with the axial bore to facilitate fluid flow from adjacent the at least one inducer vane into the axial bore.
In another embodiment, a centrifugal pump includes a pump housing including a fluid inlet and a fluid outlet. An impeller is disposed in the housing and is rotatable about a rotational axis. The impeller includes a central hub that is disposed along a rotational axis of the impeller and that defines an axial bore that extends through at least a portion of the central hub along the rotational axis. The central hub further defines an opening to the axial bore at a leading end of the central hub. The impeller further includes an impeller section that includes at least one impeller vane fixed to the central hub. The impeller section is spaced from the leading end of the central hub. The impeller further includes an inducer section that is disposed between the leading end of the central hub and the impeller section. The inducer section includes at least one inducer vane that extends along an outer surface of the central hub. The central hub defines at least one radial aperture in the inducer section. The at least one radial aperture is in fluid communication with the axial bore to facilitate fluid flow from adjacent the at least one inducer vane into the axial bore.
In another embodiment, an aircraft fuel system includes a fuel tank, a centrifugal pump, and a main fuel line. The centrifugal pump is in fluid communication with the fuel tank for receiving fuel from the fuel tank. The main fuel line in fluid communication with the centrifugal pump for receiving pressurized fuel from the centrifugal pump. The centrifugal pump includes a pump housing including a fluid inlet and a fluid outlet. An impeller is disposed in the housing and is rotatable about a rotational axis. The impeller includes a central hub that is disposed along a rotational axis of the impeller and that defines an axial bore that extends through at least a portion of the central hub along the rotational axis. The central hub further defines an opening to the axial bore at a leading end of the central hub. The impeller further includes an impeller section that includes at least one impeller vane fixed to the central hub. The impeller section is spaced from the leading end of the central hub. The impeller further includes an inducer section that is disposed between the leading end of the central hub and the impeller section. The inducer section includes at least one inducer vane that extends along an outer surface of the central hub. The central hub defines at least one radial aperture in the inducer section. The at least one radial aperture is in fluid communication with the axial bore to facilitate fluid flow from adjacent the at least one inducer vane into the axial bore.
The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and wherein:
The following detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding background or the following detailed description.
An impeller, a centrifugal pump including the impeller, and an aircraft fuel system including the centrifugal pump are provided herein. The impeller maximizes centrifugal pump efficiency, particularly when a fluid input having a high vaporized fluid content, by separating at least some vaporized fluid that travels through the impeller in an inducer section of the impeller and by returning the vaporized fluid upstream through a central hub of the impeller. By separating at least some of the vaporized fluid and returning the vaporized fluid upstream, a higher proportion of liquid is ultimately present in the fluid that is pressurized by the impeller. Because higher liquid to vapor content in fluid to be pressurized corresponds to higher pump efficiency, pump efficiency is maximized by employing the impeller described herein. Further, once the vaporized fluid is delivered upstream, and without being bound to any particular theory, pressure impingement may enable a portion of the vaporized fluid to be compressed and condensed to thereby increase a ratio of liquid to vaporized fluid in the fluid input into the impeller.
The impeller and centrifugal pump may be employed to pump any type of fluid, but are particularly suitable for pumping fluid that has a high vaporized fluid content. For example, as shown in
Referring now to
Referring to
The impeller 32 further includes an inducer section 50 and an impeller section 52. The inducer section 50 is disposed between the leading end 38 of the central hub 36 and the impeller section 52, and the impeller section 52 is spaced from the leading end 38 of the central hub 36. The inducer section 50 includes at least one inducer vane 54 for drawing fluid into the impeller 32 and effecting a slight pressure increase in the fluid in preparation for further pressurizing the fluid in the impeller section 52. For purposes herein, the inducer section 50 begins at the leading end 38 of the central hub 36 and terminates at a plane 56 that passes through the central hub 36 and a terminal edge of a rearmost inducer vane 54 relative to the leading end 38 of the central hub 36. Also for purposes herein, the impeller section 52 begins immediately following the inducer section 50.
The at least one inducer vane 54 of the inducer section 50 extends along an outer surface 58 of the central hub 36 in a configuration that is adapted to draw fluid into the centrifugal pump 10 upon rotation of the impeller 32 about the rotational axis 34. In an embodiment, as best shown in
As shown in
As shown in
In an embodiment, the at least one radial aperture 70 comprises a plurality of radial apertures 70 that are spaced along the central hub 36, along the direction of the rotational axis 34. However, it is to be appreciated that a number of radial apertures 70 and a total surface area of radial apertures 70 are subject to design considerations based upon intended fluid type, operational speeds of the impeller 32, size of the impeller 32, and other factors that affect flow dynamics of fluid through the impeller 32. Considerations regarding location of the at least one radial aperture 70 may impact siphoning of the vaporized fluid through the at least one radial aperture 70. Because the impact of vaporized fluid on pump efficiency is greater in the impeller section 52 than in the inducer section 50, in an embodiment, the at least one radial aperture 70 is defined only in the inducer section 50 and the central hub 36 is free from radial apertures 70 outside of the inducer section 50 to maximize siphoning of the vaporized fluid in the inducer section 50. In a further embodiment, the at least one radial aperture 70 is defined adjacent to the low-pressure side 66 of the at least one inducer vane 54. For example, as set forth above, the low-pressure side 66 may be located adjacent the forward inducer vane wall 62. For purposes herein, the low-pressure side 66 refers to an area of the fluid channel 60 that is in closer proximity to the forward inducer vane wall 62 than the trailing inducer vane wall 64. In this embodiment, the at least one radial aperture 70 is defined between the at least two inducer vanes 54, in the fluid channel 60, and the at least one radial aperture 70 is defined in closer proximity to the forward inducer vane wall 62 in the fluid channel 60 than to the trailing inducer vane wall 64 of the other inducer vane 54 that defines the fluid channel 60. In this manner, the at least one radial aperture 70 is positioned where the vaporized fluid is likely to concentrate within the impeller section 52 while minimizing siphoning of liquid in the fluid that is flowing through the impeller 32. In yet a further embodiment, the at least one radial aperture 70 is defined in closer proximity to the impeller section 52 than to the leading end 38 of the central hub 36, which may maximize siphoning into the axial bore 46 through the at least one radial aperture 70 due to increasing pressures in the fluid as it travels through the inducer section 50. The increasing pressures create a larger pressure differential between the fluid input at the leading end 38 of the central hub 36 and the fluid passing adjacent to the at least one radial aperture 70, thereby promoting greater siphoning of the vaporized fluid through the at least one radial aperture 70.
Due to the presence of the at least one radial aperture 70 and the axial bore 46 in the central hub 36, fluid continuing to the impeller section 52 from the inducer section 50 has a higher ratio of liquid to vaporized fluid than may otherwise exist in the absence of those features, thereby enabling more efficient pressurization of the fluid in the impeller section 52 even under conditions in which the fluid has high vaporized fluid content at the fluid inlet 28.
Referring to
While at least one exemplary embodiment has been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims.
