This present invention relates to a high efficiency, high work coefficient fan which can be used, for example, in electronics cooling applications.
Many prior art cooling fans include a motor-driven impeller which propels a stream of air through a fan housing. These fans may also comprise an outlet guide vane assembly which is positioned downstream of the impeller to both de-swirl and increase the static pressure of the air, and a diffuser section which is located downstream of the outlet guide vane assembly to decelerate and thereby further increase the static pressure of the air.
The impeller and the outlet guide vane assembly each include a plurality of radially extending blades or vanes. The shape of each blade or vane can be defined by the values of camber, chord and stagger for each of a plurality of radially spaced airfoil segments in the blade or vane, as well as the degrees of lean and bow for each of the leading and trailing edges of the blade or vane. In addition, the overall configuration of the impeller and the outlet guide vane assembly can be defined in terms of the solidity and aspect ratio of the blades or vanes as a whole.
In the inventors' experience, prior art cooling fans typically have total-to-static efficiencies of less than 60%. Low fan efficiencies require the use of larger and heavier motors which must operate at higher speeds. These motors usually require increased power to operate, generate more noise and have reduced life spans. Fan inefficiencies may result from virtually any choice made during the design process, from architecture selection through the detailed design of the flowpath surfaces, the impeller blades and the guide vanes.
Prior art cooling fans use bow and lean in the impeller blades and guide vanes in order to achieve certain desired performance characteristics. In prior art cooling fans in which the flow near the midspan of the blades or vanes is weak, however, increasing the bow and lean angles may be detrimental since it would increase the aerodynamic loading near the midspan. Because the flow near the midspan is already weak, additional loading from increased bow would lead to increased flow separation and poorer performance. This is especially true for smaller fans with lower aspect ratio impeller blades and guide vanes.
In accordance with one embodiment of the present invention, a cooling fan comprises an impeller which includes a plurality of radially extending blades, each of which includes a blade hub, a blade tip and a blade midspan approximately midway between the hub and the tip. In addition, each blade comprises a camber of between about 60° and 90° at the blade hub, between about 15° and 40° at the blade midspan and between about 15° and 40° at the blade tip.
In accordance with another embodiment of the present invention, each blade comprises a stagger of between about 15° and 40° at the blade hub, between about 45° and 65° at the blade midspan and between about 50° and 70° at the blade tip. Also, each blade may comprise a solidity of between about 1.2 and 2.2 at the blade hub, between about 1.0 and 1.7 at the blade midspan and between about 0.7 and 1.5 at the blade tip, and a chord of about 1.0 at the blade hub, between about 1.0 and 1.2 at the blade midspan and between about 0.85 and 1.25 at the blade tip.
In accordance with a further embodiment of the invention, the cooling fan comprises an outlet guide vane assembly which includes a plurality of radially extending guide vanes, each of which comprises a vane hub, a vane tip and a vane midspan approximately midway between the vane hub and the vane tip. In addition, each guide vane comprises a camber of between about 40° and 75° at the vane hub, between about 30° and 65° at the vane midspan and between about 40° and 70° at the vane tip.
In accordance with yet another embodiment of the invention, each guide vane comprises a stagger of between about 15° and 30° at the vane hub, between about 12° and 25° at the vane midspan and between about 15° and 30° at the vane tip. In addition, each guide vane may comprise a solidity of between about 1.5 and 3.0 at the vane hub, between about 1.0 and 2.0 at the vane midspan and between about 0.8 and 1.6 at the vane tip, and a chord of about 1.0 at the vane hub, between about 0.75 and 0.95 at the vane midspan and between about 0.75 and 0.95 at the blade tip.
In accordance with still another embodiment of the invention, each guide vane includes a leading edge which comprises a bow angle at the vane hub of other than 0° and a bow angle at the vane tip of other than 0°. Furthermore, each guide vane may include a trailing edge which comprises a bow angle at the vane hub of other than 0° and a bow angle at the vane tip of other than 0°. Furthermore, the leading edge of each guide vane may be swept axially aft between about 5° and 20°.
In general, the cooling fan of the present invention may include an impeller which comprises a plurality of radially extending impeller blades, an outlet guide vane assembly which comprises a plurality of radially extending guide vanes, and an optional diffuser section which is located downstream of the outlet guide vane assembly.
The impeller and the outlet guide vane assembly may be aerodynamically designed using three-dimensional computational fluid dynamics to ensure that flow weakness is minimized and efficiency is maximized. For example, the impeller blades and guide vanes may be designed using numerous tailored airfoil segments, and bow and lean may be incorporated into the blades and vanes in order to achieve maximum performance and range. In addition, the leading edge of the guide vanes may be swept aft to reduce the amount of noise generated by the fan.
Bow may be incorporated into the guide vanes to help balance the aerodynamic loading across the vanes in the spanwise direction. Increasing bow in this direction reduces the aerodynamic loading of the airfoil segments near the end walls and results in increased loading of the airfoil segments near the midspan. Bow also tends to energize the end wall boundary layers, making them less susceptible to separation. The outlet guide vanes may comprise a leading edge that is especially curved near the hub and the tip. The trailing edge may be bowed in the same direction and to a greater degree than the leading edge.
These and other objects and advantages of the present invention will be made apparent from the following detailed description, with reference to the accompanying drawings. In the drawings, the same reference numbers are used to denote similar components in the various embodiments.
The present invention is applicable to a variety of air movers. However, for purposes of brevity it will be described in the context of an exemplary vane-axial cooling fan. Nevertheless, the person of ordinary skill in the art will readily appreciate how the teachings of the present invention can be applied to other types of air movers. Therefore, the following description should not be construed to limit the scope of the present invention in any manner.
Referring to
The motor 16 includes a motor housing 28, a stator 30 which is mounted within the motor housing, a rotor 32 which is positioned within the stator, and a rotor shaft 34 which is connected to the rotor. The rotor shaft 34 is rotationally supported in a front bearing 36 which is mounted in the motor housing 28 and a rear bearing 38 which is mounted in the tail cone 26.
The impeller 18 comprises an impeller hub 40 which is connected to the rotor shaft 34 by suitable means and a number of impeller blades 42 which extend radially outwardly from the impeller hub. The impeller hub 40 is sloped so that the annular area around the upstream end of the impeller 18 is larger than the annular area around the downstream end of the impeller. As is known in the art, this configuration reduces the static pressure rise of the air across the impeller 18. The impeller hub 40 may also include a removable nose cone 44 to facilitate mounting the impeller 16 to the rotor shaft 34.
Examples of four impellers 18 which are suitable for use in the present invention are shown in
Referring still to
In operation of the cooling fan 10, the motor 16 spins the impeller 18 to draw air into and through the fan housing 12. The converging inlet 14 delivers a uniform, axial air stream to the impeller 18 and contracts the air stream slightly to mitigate the performance and noise penalties normally associated with inlet flow distortion. As the air stream flows through the impeller 18, the sloping impeller hub 40 reduces the static pressure rise of the air stream. The guide vanes 50 then receive the swirling air stream from the impeller 18 and turn the air stream in substantially the axial direction. In the process of deswirling the air stream, the static pressure of the air increases. The diffuser section 22 receives the air stream from the outlet guide vane assembly 20 and decelerates it to further increase the static pressure of the air.
Each of the impeller blades 42 and the outlet guide vanes 50 may be considered to comprise a radial stack of a number of individual airfoil segments. As shown in
Referring to
Other terms used to characterize the shape of an impeller and an outlet guide vane assembly are solidity and aspect ratio. Solidity is defined as the ratio of the chord of an airfoil segment to the spacing between that segment and a tangentially adjacent airfoil segment. Aspect ratio is defined as the ratio of the average height of the blade or vane to the average chord of the blade or vane.
The shape of the impeller blades 42 is important to achieving high efficiency and reducing the rotational speed required for a given pressure rise. In accordance with the present invention, each impeller blade 42 comprises the preferred values of camber, stagger, solidity and normalized chord set forth in Table 1.
In accordance with an exemplary embodiment of the invention, each impeller blade 42 comprises the values of camber, stagger, solidity and normalized chord shown in
The shape of the outlet guide vanes 50 is also important to achieving the required performance characteristics for a given application. In accordance with the present invention, each guide vane 50 comprises the preferred values of camber, stagger, solidity and normalized chord set forth in Table 2.
In accordance with an exemplary embodiment of the invention, each guide vane 50 comprises the values of camber, stagger, solidity and normalized chord shown in
Representative aspect ratios for the impeller and outlet guide vane embodiments depicted in
When the two-dimensional airfoil segments 52 are stacked together to form the impeller blades 40 and the guide vanes 50, the locus of the leading edge points forms the leading edge line of the blade or vane and the locus of the trailing edge points forms the trailing edge line of the blade or vane. These leading and trailing edge lines can take a variety of forms: they may be straight and radial, they may be straight with lean, or they may be curved, introducing bow into the blade or vane.
Bow and lean are conventionally used in impeller blades. However, the use of these features in the guide vanes 50 of the present invention is believed to be unique. Bow is incorporated into the guide vanes 50 to help balance the aerodynamic loading in the spanwise direction of the vanes. Increasing bow in this direction reduces the aerodynamic loading of the airfoil segments 52 near the endwalls (i.e., the radially inner and outer ends of the vanes) and results in increased loading of the airfoil segments near the midspan of the vanes. Bow also tends to energize the end wall boundary layers, making them less susceptible to separation.
Referring to
A convenient way to describe bow and lean for a general leading or trailing edge curve is illustrated in
To quantify bow, a triangle is drawn between the trailing edge hub point, the trailing edge tip point and a point on the trailing edge curve which is farthest from the line connecting these two points. The angles θhb and θtb of this triangle describe the degree of bow at the hub and the tip, respectively, of the blade or vane. Positive bow angles for an impeller blade trailing edge and a guide vane trailing edge are shown in
Representative values of lean and bow for the impeller and outlet guide vane embodiments depicted in
In accordance with a further aspect of the invention, which is illustrated in
When incorporated into the cooling fan 10, the impeller and outlet guide vane assembly configurations discussed above yield relatively large efficiencies. One measure of a fan's efficiency is the total-to-static efficiency. This value is given by the following equation:
ηT-S=[(Ps,exit/Pt,inlet)^(γ−1/γ)−1]/[(Tt,exit/Tt,inlet)−1], (1)
where Ps,exit is the exit static pressure, Pt,inlet is the inlet total pressure, Tt,inlet is the inlet total temperature, Tt,exit is the exit total temperature, and γ is the specific heat ratio of the working fluid.
Another measure of a fan's efficiency is the total-to-total efficiency, which is given by the following equation:
ηT-T=[(Pt,exit/Pt,inlet)^(γ−1/γ)−1]/[(Tt,exit/Tt,inlet)−1] (2)
where Pt,exit is the exit total pressure, Pt,inlet is the inlet total pressure, Tt,inlet is the inlet total temperature, Tt,exit is the exit total temperature, and γ is the specific heat ratio of the working fluid.
When constructed in accordance with the present invention, each embodiment of the cooling fan 10 was found to have a total-to-static efficiency near 70% and a total-to-total efficiency near 90%. These efficiencies are a considerable improvement over many prior art cooling fans.
Another measure of the performance of a fan is Work Coefficient, which is defined by the following formula:
Work Coefficient=(2×ΔH)/u2, (1)
where ΔH is the total enthalpy rise and u is the impeller inlet pitch line wheel speed. In accordance with the present invention, the Work Coefficient for the cooling fan 10 is between about 1 and 1.5.
It should be recognized that, while the present invention has been described in relation to the preferred embodiments thereof, those skilled in the art may develop a wide variation of structural and operational details without departing from the principles of the invention. For example, the various elements shown in the different embodiments may be combined in a manner not illustrated above. Therefore, the appended claims are to be construed to cover all equivalents falling within the true scope and spirit of the invention.
This application is based on and claims the benefit of U.S. Provisional Patent Application No. 60/905,248, which was filed on Mar. 5, 2007.
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