Abstract

The future trend of clean sky aviation has led to a smaller core engine, resulting in highly loaded stages with increased relative tip gaps and leakage flows, which causes a reinforced influence of secondary flow phenomena. This article experimentally investigates the secondary flow effects in the 3D-optimized shrouded stator of the TUDa-GLR-OpenStage, representative of a transonic high-pressure compressor front stage, and its susceptibility to typical hub leakage flows. The impact of stator hub leakage on efficiency and total pressure ratio is investigated for several operating speeds, from subsonic to nominal transonic operating conditions. Steady five-hole probe and time-resolved virtual multi-hole probe measurements at different operating conditions at nominal speed are conducted to investigate the underlying loss mechanisms. The leakage mass flow is determined using the measured pressure difference within the fin seal. Steady results show that the optimized 3D stator effectively suppresses the hub corner separation compared to the predecessor 2D stator, but its performance is further limited by a near-tip separation. With the increased stator hub leakage (at a leakage-to-main flow ratio of about 0.4%), the compressor isentropic efficiency generally drops (by about 0.5%) at the full operating range due to an enhanced hub corner separation effect. However, the increased leakage also helps alleviate the tip-corner separation when operating near stall, leading to a smaller efficiency penalty under these conditions. Unsteady results reveal the sensitivity of transient compressor performance to the passing rotor wake, but limited interaction between this phenomenon and the increased leakage is observed. These findings provide insight into the stator hub leakage-related penalties on the compressor aerodynamics efficiency.

Graphical Abstract Figure
Graphical Abstract Figure
Close modal

References

1.
Klausmann
,
F.
,
Franke
,
D.
,
Foret
,
J.
, and
Schiffer
,
H.-P.
,
2022
, “
Transonic Compressor Darmstadt—Open Test Case Introduction of the Tuda Open Test Case
,”
J. Global Power Propuls. Soc.
,
6
, pp.
318
329
. .
2.
Siller
,
U.
,
Voß
,
C.
, and
Nicke
,
E.
,
2009
, “
Automated Multidisciplinary Optimization of a Transonic Axial Compressor
,”
47th AIAA Aerospace Sciences Meeting Including The New Horizons Forum and Aerospace Exposition
,
Orlando, FL
,
Jan. 5–8
, p.
863
.
3.
Bakhtiari
,
F.
,
Wartzek
,
F.
,
Leichtfuß
,
S.
,
Schiffer
,
H.-P.
,
Goinis
,
G.
, and
Nicke
,
E.
,
2015
, “
Design and Optimization of a New Stator for the Transonic Compressor Rig at TU Darmstadt
,”
Deutscher Luft- und Raumfahrtkongress 2015
,
Rostock, Germany
,
Sept. 22–24
.
4.
Hergt
,
A.
,
Meyer
,
R.
,
Müller
,
M. W.
, and
Engel
,
K.
,
2008
,
Loss Reduction in Compressor Cascades by Means of Passive Flow Control
,”
Volume 6: Turbomachinery, Parts A, B, and C of Turbo Expo: Power for Land, Sea, and Air
,
Berlin, Germany
,
June 9–13
, pp.
269
280
.
5.
He
,
X.
,
Zhu
,
M.
,
Xia
,
K.
,
Klausmann
,
F.
,
Teng
,
J.
, and
Vahdati
,
M.
,
2023
, “
Validation and Verification of Rans Solvers for Tuda-Glr-Openstage Transonic Axial Compressor
,”
J. Global Power Propuls. Soc.
,
7
, pp.
13
29
. .
6.
Xia
,
K.
,
He
,
X.
,
Zhu
,
M.
,
Klausmann
,
F. S.
,
Teng
,
J.
, and
Vahdati
,
M.
,
2023
, “
Endwall Geometric Uncertainty and Error on the Performance of Tuda-glr-openstage Transonic Axial Compressor
,”
J. Global Power Propuls. Soc.
,
7
, pp.
113
126
.
7.
Hormel
,
S.
,
Franke
,
D.
,
Foret
,
J.
,
Schiffer
,
H.-P.
,
Fröbel
,
T.
, and
Schiffer
,
H. P.
,
2019
, “
Experimental Investigation of a Transonic Compressor With High Aspect Ratio Rotor Design
,”
Proceedings of Global Power and Propulsion Society
, Beijing, China, pp.
1
10
.
8.
Breugelmans
,
F. A. H.
,
Carels
,
Y.
, and
Demuth
,
M.
,
1984
, “
Influence of Dihedral on the Secondary Flow in a Two-Dimensional Compressor Cascade
,”
ASME J. Eng. Gas Turbines Power
,
106
(
3
), pp.
578
584
.
9.
Sasaki
,
T.
, and
Breugelmans
,
F.
,
1998
, “
Comparison of Sweep and Dihedral Effects on Compressor Cascade Performance
,”
ASME J. Turbomach.
,
120
(
3
), pp.
454
463
.
10.
Weingold
,
H. D.
,
Neubert
,
R. J.
,
Behlke
,
R. F.
, and
Potter
,
G. E.
,
1995
, “
Reduction of Compressor Stator Endwall Losses Through the Use of Bowed Stators
,”
Volume 1: Turbomachinery of Turbo Expo: Power for Land, Sea, and Air
,
Houston, TX
,
June 5–8
, p.
V001T01A096
.
11.
Fischer
,
A.
,
Riess
,
W.
, and
Seume
,
J. R.
,
2004
, “
Performance of Strongly Bowed Stators in a Four-Stage High-Speed Compressor
,”
ASME J. Turbomach.
,
126
(
3
), pp.
333
338
.
12.
Egli
,
A.
,
1937
, “
The Leakage of Gases Through Narrow Channels
,”
J. Appl. Mech.
,
4
(
2
), pp.
A63
A67
.
13.
Stodola
,
A.
,
1922
,
Dampf-und Gasturbinen: Mit Einem Anhang über Die Aussichten Der Wärmekraftmaschinen
,
Springer
,
Berlin/Heidelberg
.
14.
Zalf
,
G.
, and
Zvyagintsev
,
V.
,
1961
,
Thermal Calculation of Steam Turbines
,
Leningrad, Russia
(in Russian).
15.
Vermes
,
G.
,
1961
, “
A Fluid Mechanics Approach to the Labyrinth Seal Leakage Problem
,”
J. Eng. Power
,
83
(
2
), pp.
161
169
.
16.
Becker
,
B.
,
Kupijai
,
P.
, and
Swoboda
,
M.
,
2009
, “
High Fidelity CFD on a High-Speed 4.5-Stage Compressor by Means of the Non-Linear Harmonics Approach and Transition Model
,”
8th European Turbomachinery Conference
,
Gratz, Austria
,
Mar. 23–27
.
17.
Wellborn
,
S. R.
, and
Okiishi
,
T. H.
,
1999
, “
The Influence of Shrouded Stator Cavity Flows on Multistage Compressor Performance
,”
ASME J. Turbomach.
,
121
(
3
), pp.
486
497
.
You do not currently have access to this content.