This application claims priority to German Patent Application DE 10 2005 060 699.7 filed Dec. 19, 2005, the entirety of which is incorporated by reference herein.
The present invention relates to variable stator blades of turbomachines, such as blowers, compressors, pumps and fans of the axial, semi-axial or radial type. The working medium (fluid) may be gaseous or liquid.
More particularly, this invention relates to at least one variable stator blade of a turbomachine or to a variable inlet guide vane assembly, if applicable. The respective blading is situated within a casing, which confines the passage of fluid through at least one rotor and one stator in the outward direction. While a rotor comprises several rotor blades attached to a rotating shaft and transfers energy to the working medium, a stator consists of several stator blades mostly fixed in the casing.
The aerodynamic roadability and the efficiency of turbomachines, for example blowers, compressors, pumps and fans, is limited in particular by the growth and the separation of boundary layers in the area of the radial gaps between the blading and the casing or the hub, respectively, these gaps being necessary at the annulus rim for reasons of design.
In particular on rotatable variable stators, the radial gaps generated by the required recesses before and after the trunnion are pronounced and entail considerable flow losses. In order to limit these losses, rotary bases of max possible size are usually used on the inward and outward ends of the variable stators to keep small the extension of the recesses in flow direction. Preferably, the rotary bases are provided such that they are situated in the crucial profile leading edge zones of the blade peripheral sections.
However, due to failure provisions and design constraints, configurations of variable stators quite frequently exist which have only small size and where the rotary bases are not situated far enough upstream. In this case, a considerable radial gap exists both before and after the rotary base. The state of the art does not provide any aerodynamically favorable solutions to this fundamental problem. The general concept of boundary influencing of radial running gaps by changing the type of skeleton line along the blade height is provided in the state of the art, however, the known solutions are not adequate and, therefore, not effective, in particular for the flow conditions at a blade end with rotary base and two partial radial gaps.
On the left-hand side, a conventional variable stator without variation of the type of skeleton line is shown. In this simplest standard case, the blade consists of only one block (Z0) in which the type of the skeleton line is specified according to fixed rules. This category includes the so-called CDA (controlled diffusion airfoils) according to U.S. Pat. No. 4,431,376. Aerodynamically, CDA aim at a moderate profile front load.
On the right-hand side, a conventional blade is shown whose rotating base extends up to the leading edge. In lieu of a completely uniform profile, the blade may also feature a continuous change of the profile type over the entire height according to the state of the art. Here, the entire blade is not represented by a block (Z0) of uniform profile, but by only one large transition zone. This includes concepts from known publications providing for a transition from a CDA type of skeleton line to a type of skeleton line that aims more at a profile back load in the blade outer areas (R. F. Behike, Journal of Turbomachinery, Vol. 8, July 1986).
In addition, attempts exist to positively influence the peripheral zone flow by specially shaping the blade stacking axis, for example by imparting a bend, sweep or dihedral to the blading (see EP0661413A1, EP1106835A2, EP1106836A2). None of the existing solutions refers to variable stators.
The present invention relates to stators which are rotatably borne on at least one blade end and are variable around a fixed rotating axis by a trunnion. As in all representations shown herein, inflow to the respective blade row is from the left to the right in the direction of the bold arrow.
The state of the art is disadvantageous in that the respective blade forms are designed, often deliberately, with low complexity regarding the shape of the skeleton line. Where different types of skeleton lines along the blade height are used, the character of the skeleton lines lacks block-wise markedness which would allow the profile pressure distribution in wall vicinity to be stronger influenced to obtain the max. possible degree of gap and peripheral flow steadying. In particular with variable stators, there is a lack of blade concepts with skeleton line variations along the blade height which appropriately combine a profile front load favorable in the blade mid area with a type of load distribution favorable for the peripheral areas.
A broad aspect of the present invention is to provide a variable stator blade of the type specified above which, while avoiding the disadvantages of the state of the art, is characterized by exerting a highly effective influence on the peripheral flow due to a specific and problem-oriented block-wise definition of the profile skeleton lines along the blade height.
It is a particular object of the present invention to provide solutions to the above problems by a combination of the features described herein. Further advantageous embodiments of the present invention will become apparent from the description below.
The present invention provides for a variable stator blade for use in a turbomachine which features defined types of profile skeleton lines in different zones (blocks) of the blade height, limited by meridional flow lines, with the proviso that
The present invention is more fully described in light of the accompanying drawings showing examples of embodiments. In the drawings,
a shows a variable stator (borne in casing and hub) “SGN” according to the present invention,
b shows a variable stator (borne in casing) “SG” according to the present invention,
c shows a variable stator (borne in hub) “SN” according to the present invention,
d provides the allocation of the blade zones Z1, Z0, Z2 according to the present invention and of the defined types of skeleton lines PM and PR,
a provides the definition of the skeleton line of a flow line profile section,
b provides the definition of the type of profile skeleton line “PM” for the blade mid zone,
c provides the definition of the type of profile skeleton line “PR” for the blade peripheral zone at a rotating axis position of D=0.3,
d provides the definition of the type of profile skeleton line “PR” for the blade peripheral zone at a rotating axis position of D=0.5.
a shows the variable stator blade borne in casing and hub “SGN” according to the present invention in the meridional plane defined by the axial coordinate x and the radial coordinate r. Here, the blade peripheral zones Z1 and Z2, the transition zones T1 and T2 and the blade mid zone Z0 are highlighted and limited by the respective meridional flow lines according to the definition in
Analogically with this representation,
d shows in tabulated form the allocation according to the present invention of the three blade zones Z1, Z0, Z2 and of the types of skeleton lines PM and PR specified below (
PM—Type of profile skeleton line for the blade mid zone,
PR—Type of profile skeleton line for the blade peripheral zone.
HSV=5·H/(LSL10+LSL30+LSL50+LSL70+LSL90)
The zone widths are determined in dependence of the height-to-side ratio in relative form (related to the total duct width W) according to the following rule:
WZ1/W=WZ2/W=(0.06·HSV0.65)/HSV
WT1/W=WT2/W=(0.30·HSV0.80)/HSV
WZ0/W=1−WZ1/W−WT1/W−WZT2/W−WZ2/W
The respective type of skeleton line is defined in relative representation by way of the specific angle of inclination α* and the specific extension s*, ref.
For this, the angle of inclination αp and the extension sp covered so far are determined in all points of the skeleton line. For reference, the inclination angle at the leading and the trailing edge α1 and α2 and the skeleton-line total extension S are used. The following applies:
α*=(α1−αp)/(α1−α2) and s*=sp/S.
b shows the definition of the type “PM” of the skeleton line in the known relative representation. Skeleton line extensions according to the present invention are above the boundary line. Skeleton line extensions in the excluded area below and on the boundary line do not comply with the present invention. The boundary line for the type “PM” of the skeleton line is given by the following definition:
α*=−3.8512520965(s*)6+14.6764714420(s*)5−21.6808727924(s*)4+16.3850592743(s*)3−6.9703863077(s*)2+2.4431236235(s*)−0.0060854622
A skeleton line distribution provided according to the present invention for the block at the blade center is delineated by way of example.
c and 6d show the definition of the type “PR” of the skeleton line in the known relative representation for the rotating axis positions d*=0.3 and d*=0.5. Skeleton line extensions according to the present invention are below the continuous upper boundary line and above the lower boundary line given at a certain interval. Skeleton line extensions in the excluded area above and on the upper boundary line do not comply with the present invention. Skeleton line extensions below or on the lower boundary line do not comply with the present invention either.
Depending on the relative rotating axis positions d* the boundary lines for the type “PR” of the skeleton line are given by the following definitions:
Upper boundary line for d*=0.3:
α*=−15.1441661664(s*)6+52.8168915277(s*)5−67.2135203453(s*)4+35.9670881201(s*)3−6.8146566070(s*)2+1.3350483823(s*)+0.0535731815
Upper boundary line for d*=0.5:
α*=3.6478453237(s*)6−5.6044881912(s*)5−5.3211690262(s*)4+11.7583720270(s*)3−4.3361971934(s*)2+0.8062070974(s*) +0.0502599068
For rotating axis positions d* unequal to 0.3 and 0.5, the values of α* are to be determined by linear interpolation between those for d*=0.3 and d*=0.5.
α*(d*)=α*(d*=0.5)+[α*(d*=0.3)−α* (d*=0.5)]*[0.5−d*]/0.2
Lower boundary:
α*=2.0(s*)−2d*
Applicable at the interval of s*: (d*+0.1; d*+0.3)
In
With the blade for turbomachines, such as blowers, compressors, pumps and fans, according to the present invention, peripheral flow influencing is achieved which is capable of increasing the efficiency of each stage by approx. 1 percent, with stability remaining unchanged. In addition, a reduction of the number of blades of up to 20 percent is possible. The concept according to the present invention is applicable to different types of turbomachines and, depending on the degree of utilization of the concept, yields savings in cost and weight of the turbomachine of 2 to 10 percent. In addition, the overall efficiency of the turbomachine is increased by up to 1.5 percent, depending on the application.
Number | Date | Country | Kind |
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10 2005 060 699 | Dec 2005 | DE | national |
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2324950 | Sep 1999 | CA |
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Number | Date | Country | |
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20070140837 A1 | Jun 2007 | US |