Patent Grant
8647051
The present invention relates to cooling systems for computers and other electronic devices, and more particularly to low-profile, compact centrifugal air impellers designed to operate at high speeds.
Designers of a wide variety of electronic devices continually strive to provide more utility in smaller packages. Notebook or laptop computers illustrate this trend, in terms of the ongoing efforts to reduce their size and at the same time enlarge their capacity and capability to store and manipulate data. These devices generate heat during use, with increased functionality leading to increased heat generation. Failure to remove excess heat subjects these devices to a variety of risks ranging from reduced efficiency to serious and permanent damage.
Thus, designers of cooling systems for these devices face the dual and competing goals of smaller size and increased capacity for removing heat.
Typically, notebook computers have been designed to incorporate an internal housing or compartment for a dual-inlet, centrifugal type fan. In one conventional design, blades of constant thickness are attached directly to a rotor hub at their leading edges and extend away from the hub in “backwardly-inclined” fashion. This design can be molded with relative ease at low cost, but entails several disadvantages that become more pronounced in a reduced size, higher speed environment. One is the lack of an aerodynamically effective approach to drawing air into the blades. High speeds lead to distortion of the blades, further reducing efficiency and generating unwanted noise.
Efforts to solve these problems have lead to designs featuring structural or guide members along the blades, either on the positive pressure side as in U.S. patent application, Publication No. 2008/0130226 (Yamashita et al.), or on the leeward side as in U.S. patent application, Publication No. 2009/0028710 (Horng et al.). Another known approach involves selectively varying the blade thickness as shown in U.S. Pat. No. 6,579,064 (Hsieh) and U.S. Pat. No. 7,118,345 (Wu et al.).
In yet another approach the blades, particularly including their leading edges, are separated from the primary hub structure. This has been accomplished with an angular plate extending from the hub as shown in U.S. Pat. No. 6,568,907 (Horng et al.), or with a ring supported radially outwardly from the hub, as in U.S. patent application, Publication No. 2008/0226446 (Fujieda) and the aforementioned Wu patent.
Yet another approach is to support the blades individually with posts or other members at their leading edges. Examples of this approach include U.S. Pat. No. 7,063,510 (Takeshita et al.) and U.S. patent application, Publication No. 2007/0274834 (Huang et al.).
Although the forgoing examples and similar approaches have led to improved performance compared to the directly attached linear constant thickness blade design, the above-identified problems persist. Accordingly, the present invention is characterized by several aspects directed to one or more of the following objects:
To achieve theses and other objects, there is provided a centrifugal fan. The fan includes a hub rotatable on a hub axis. The hub has a hub outer periphery disposed circumferentially about the hub axis. The fan comprises a plurality of blades. A blade mounting structure, narrower axially than the blades, supports the blades integrally relative to the hub and spaced apart from the hub in a circumferential sequence about the hub. The mounting structure supports the blades for rotation with the hub about the hub axis in a forward rotational direction to determine in each blade a leading edge and a trailing edge. Each blade comprises a forward region encompassing the leading edge and a rearward region behind the forward region and encompassing the trailing edge. The blade mounting structure comprises a plurality of blade-supporting struts. Each strut is coupled to the hub periphery, to the rearward region of a first one of the blades associated with the strut, and to the forward region of a second one of the blades associated with the strut. The second associated blade immediately follows the first associated blade in the sequence.
A prominent feature of the centrifugal fan is the combination of two-point anchoring of each blade and a one-to-one correspondence of struts to blades. Securing each blade at its forward region and at its rearward region reduces blade distortion and vibration. This is advantageous in any event and particularly at high speeds. For example, while conventional centrifugal fans of this kind typically are operated at rotational speeds up to 5,000 RPM (revolutions per minute), fans with two-point anchoring pursuant to the present invention can be operated at speeds up to 10,000 RPM with minimal blade distortion. Supporting each blade with two struts rather than one allows the use of reduced profile, lighter weight struts. Each pair of struts supporting a blade can have a combined mass comparable to a single strut in prior designs. Smaller struts with more aerodynamic profiles lead to less turbulent flow across the blade surfaces.
In preferred versions of the fan, the struts are recessed from the blade leading and trailing edges. This leaves portions of the forward and rearward blade regions with smooth profiles uninterrupted by the struts, to promote a more laminar and less turbulent air flow.
To further enhance air flow, each of the struts has an axial thickness less than its circumferential width. The axial thickness advantageously varies gradually between a maximum thickness along a medial region of the strut and reduced thicknesses at the strut forward and rearward edge portions.
Another aspect of the invention is a centrifugal impeller. The centrifugal impeller includes a hub rotatable on a hub axis and having a hub outer periphery disposed circumferentially about the hub axis. The impeller further includes a plurality of blades. A blade mounting structure, narrower axially than the blades, supports the blades integrally relative to the hub and spaced apart from the hub in a circumferential sequence about the hub for rotation with the hub about the hub axis in a forward direction. This determines in each blade a leading edge and a trailing edge. The blade mounting structure further supports the blades inclined relative to the hub. This selects one of the leading and trailing edges as a proximate edge spaced radially from the hub outer periphery by a first distance, and selects the other of the leading and trailing edges as a remote edge spaced radially from the hub outer periphery by a second distance greater than the first distance. The blade mounting structure comprises a plurality of first structural segments coupled with respect to the hub and associated individually with the blades. Each first structural segment is coupled to its associated blade at a first location near the proximate edge. The blade mounting structure further comprises a plurality of second structural segments associated individually with adjacent pairs of the blades. Each second structural segment is coupled to a first blade of its associated pair at a second location between the first location and the remote edge, and further is coupled to a second blade of the associated pair to couple said first and second blades.
The impeller features a blade mounting structure that supports each blade with structural segments at two locations, a first location near the proximate edge and a second location between the first location and the remote edge. Two spaced apart structural segments, preferably struts, replace a single, massive blade mounting structure. Accordingly, the advantages of increased stability and more aerodynamically effective air flow can be achieved as compared to the single blade mounting structure. To further improve air flow, the first and second locations can be recessed from the proximate edge and remote edge, respectively.
In one version of the impeller, the second structural segment is coupled to the second blade of the associated pair at a location that coincides with the first location. The second structural segment and its associated first structural segment are aligned end to end, and resemble a single strut extending from the hub and through the second blade toward a point of attachment to the first blade. In an alternative version of the impeller, the second structural segment is coupled to the second blade at a third location disposed between the first location and the second location.
In preferred versions of the impeller, the blades are backwardly curved. In these versions, the proximate edge of each blade is the leading edge, and the remote edge is the trailing edge. However, the principles can as well be applied to impellers with forwardly curved blades to achieve similar advantages.
Another aspect of the invention is an aerodynamic centrifugal fan impeller. The impeller includes a hub rotatable on a hub axis and having a hub outer periphery disposed circumferentially about the hub axis. The impeller further includes a plurality of blades. A plurality of blade-supporting struts are integrally coupled to the blades and to the hub periphery to support the blades radially spaced apart from the hub in a circumferential sequence about the hub. The struts support the blades for rotation with the hub about a hub axis in a forward rotational direction to determine in each blade a leading edge and a trailing edge. Each blade further comprises a forward region encompassing the leading edge, a rearward region encompassing the trailing edge, and a medial region between the forward region and the rearward region. Each of the blades has a blade width in the axial direction, and a blade thickness that varies gradually between a first thickness proximate the leading edge and a second thickness along the medial region. The blade thickness further varies gradually between the second thickness and a third thickness proximate the trailing edge. Each of the first and third thicknesses is less than the second thickness. Each of the struts has a circumferential width, and an axial thickness less than the blade width that varies gradually between a maximum thickness along a medial portion of a strut and reduced thicknesses at forward and rearward edge portions of the strut.
Thus, the blades and the struts have thickness profiles that diverge from a forward edge to a maximum thickness along a medial region or midportion, then converge to a reduced thickness at a rearward edge. This promotes a smoother, more laminar air flow in the rearward direction along the blades and struts. The profiles can be curved on one side, curved on both sides, or substantially identically curved on both sides to be symmetrical about a bisecting plane. In a particularly preferred version, the thickness of the blades is controlled to provide a maximum thickness along the medial region ranging from 1.25 to 1.40 times the blade thickness at the leading edge.
Mounting of the struts to the blades at locations recessed from the leading and trailing edges further enhances aerodynamic performance. Each of the struts can be coupled to one of the blades at its forward region and to the next adjacent blade at its rearward region, for improved stability with a one-to-one correspondence of struts and blades as previously noted. To further enhance this feature in an impeller with rearwardly curved blades, the struts can be curved forwardly in a generally radial direction of extension away from the hub.
Thus in accordance with the present invention, a centrifugal impeller locates the impeller blades spaced apart from the hub in a secure, stable fashion to minimize distortion and vibration at high speeds, and with considerably improved aerodynamic performance for more effective heat dissipation.
For a further understanding of the above and other features, reference is made to the following detailed description and to the drawings, in which:
Turning now to the drawings, there is shown in
The cooling system includes a housing 18 with a top wall 20 and a bottom wall 22 that determine a circular housing profile, and an annular side wall 24. A central opening 26 in the top wall, and a similarly sized central opening 28 in the bottom wall, provide opposite side inlets that accommodate the flow of air into the cooling system. Air flow out of the system is accommodated in a known manner by one or more openings through side wall 24, not shown.
Housing 18 contains an impeller 30 and a motor for rotating the impeller about a vertical impeller axis relative to the housing. Components of the motor include stator windings 32 arranged about the axis and fixed with respect to the housing. Impeller 30 includes a central hub 34 mounted on a spindle 36 for rotation about the impeller axis. The hub integrally contains several motor components, including a back iron and one or more permanent magnets.
As seen in
A plurality of struts 40 support blades 38 in radially spaced apart relation to hub 34. There is a one-to-one correspondence of struts to blades, in that each blade is supported by two of the struts and each of the struts supports two adjacent blades.
As indicated by the arrow in
With further reference to
Likewise, each blade is supported by two adjacent struts. Blade 38b, for example, is supported at its forward region 46b by strut 40b, and supported at its rearward region 48b by strut 40c.
Impeller 30 preferably is formed as a single piece by injection molding, using an engineered plastic such as glass-filled nylon or a metal such as magnesium. Accordingly, strut 40b “extends through” blade 38b on the way to blade 38a in a functional rather than literal sense. Alternatively, strut 40b might be considered to include a radially inward strut segment mounting blade 38b with respect to hub 34, and a radially outward strut segment mounting blade 38a with respect to blade 38b. In any event, each strut is integrally coupled to the hub, the forward region of an associated strut, and the rearward region of the adjacent associated strut to firmly support the blades in a manner that minimizes distortion and vibration.
Blades 38 are aerodynamically designed for enhanced air flow through system 16. Each blade has a diverging and converging thickness. More particularly, the thickness increases gradually from leading edge 42 to maximum thickness along medial region 50, then diminishes gradually to a reduced thickness at trailing edge 44. In blades 38, this is accomplished primarily through selective curvature of a positive pressure side 52 and to a lesser extent the curvature of a suction side 54 of the blade.
In preferred versions of blade 38, the maximum thickness ranges from 1.25 to 1.40 times the thickness at the leading edge. This ratio, combined with the progressive and gradual increase in thickness backwardly from the leading edge, provides optimal efficiency by minimizing separation of airflow across the blade surfaces.
A selective curvature of positive pressure side 52 can afford the additional advantage of determining or setting the blade inlet angle and blade discharge angle independently of one another. The blade inlet angle is the angle between the meanline near the leading edge and a tangent of the hub taken at the leading edge. The discharge angle is the angle between the meanline near the blade trailing edge and a tangent of a circle centered on the hub axis with a radius extending to the trailing edge. As an example, in preferred versions of the impeller the inlet angle ranges from 22 degrees to 30 degrees, and the discharge angle ranges from 44 degrees to 52 degrees.
In the preferred impeller, the struts are centered on a reference plane (not illustrated) passing through the hub and perpendicular to the hub axis. More preferably, the reference plane is axially centered with respect to the hub. In alternative impellers, the struts are staggered to position adjacent struts on opposite sides the reference plane. The staggered arrangements require an even number of struts, and thus require an even number of blades in arrangements featuring a one-to-one correspondence of struts to blades. Staggered struts may be parallel to or inclined relative to the reference plane.
In an embodiment of the invention the struts are substantially equally spaced about the hub. Also, in an embodiment of the invention each of the struts is substantially centered with respect to a plane perpendicular to the hub axis. Further, in an embodiment of the invention the blades have a substantially constant width in the axial direction. Additionally, in an embodiment of the invention the axial width of the blades is substantially constant. Further, in an embodiment of the invention the struts are substantially equally spaced about the hub. Also, in an embodiment of the invention the struts are substantially centered with respect to a plane perpendicular to the hub axis.
Impellers designed in accordance with the present invention are more efficient in terms of the air power output generated in response to a given level of input power.
Three different impellers were tested in the same system. One of the impellers was a conventional design in which the impeller blades were linear and of constant thickness. The blades were backwardly inclined. The blades were attached directly to the hub, with their leading edges contiguous with the hub. This design is represented by the bar labeled “C” in
A second impeller was like the first in that its blades were of constant thickness and their leading edges were contiguous with the hub. This impeller differed from the first in that its blades were backwardly curved. This design is represented by the bar labeled “B” in the chart.
The final impeller, represented by the bar labeled “A,” also had backwardly curved blades. In accordance with the present invention, the thickness of the blades varied gradually between a maximum thickness along a medial region of the blade and reduced thicknesses near the blade leading and trailing edges. Further, the leading edges of the blades were spaced apart radially from the hub, supported relative to the hub by aerodynamically designed struts.
A comparison of the bars B and C in
In accordance with the present invention, an impeller for a centrifugal fan is improved structurally and aerodynamically for moving more air through a cooling system at higher speeds. The impeller blades are supported in spaced apart relation to the hub at locations proximate but recessed from the blade leading and trailing edges, to provide a favorable combination of smoother air flow and increased stability. Multiple strut-to-blade couplings enable the use of smaller, lighter weight struts to provide the desired stability. Aerodynamically designed struts further enhance airflow.
This application claims the benefit of priority based on Provisional Application No. 61/242,853 entitled “High Efficiency Low-Profile Centrifugal Fan,” filed Sep. 16, 2009.
| Number | Name | Date | Kind |
|---|---|---|---|
| 65252 | McKenzie | May 1867 | A |
| 195865 | Wilson | Oct 1877 | A |
| 1779026 | Wragg | Oct 1930 | A |
| 3708244 | Dawson et al. | Jan 1973 | A |
| 4326836 | Fitton | Apr 1982 | A |
| 6206641 | Park et al. | Mar 2001 | B1 |
| 6345956 | Lin | Feb 2002 | B1 |
| 6568907 | Horng et al. | May 2003 | B2 |
| 6579064 | Hsieh | Jun 2003 | B2 |
| D486569 | Chen et al. | Feb 2004 | S |
| 7063510 | Takeshita et al. | Jun 2006 | B2 |
| 7118345 | Wu et al. | Oct 2006 | B2 |
| D587363 | Rheault | Feb 2009 | S |
| 8202055 | Wu et al. | Jun 2012 | B2 |
| 20020127113 | Kwon et al. | Sep 2002 | A1 |
| 20040258527 | Kaneko et al. | Dec 2004 | A1 |
| 20050058543 | Takeshita et al. | Mar 2005 | A1 |
| 20050249604 | Wu et al. | Nov 2005 | A1 |
| 20070065279 | Lin et al. | Mar 2007 | A1 |
| 20070217908 | Ochiai et al. | Sep 2007 | A1 |
| 20070274834 | Huang et al. | Nov 2007 | A1 |
| 20080130226 | Yamashita et al. | Jun 2008 | A1 |
| 20080226446 | Fujieda | Sep 2008 | A1 |
| 20090028710 | Horng et al. | Jan 2009 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 20110064570 A1 | Mar 2011 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61242853 | Sep 2009 | US |
