Bleed off-take air pressure and the interaction of the off-take with the primary flow through the blade passage is determined by: (1) the location of the bleed off-take at the endwall relative to the blade passage; (2) the bleed flow rate; and (3) the off-take geometry. In the companion paper (Leishman et al., 2007, ASME J. Turbomach., 129, pp. 645–658) the effect of bleed rate and endwall location was investigated using a circular hole bleed off-take configuration; the circular hole was tested at three endwall locations and for bleed flow rates between 0% and 9% of the primary (core) flow through the blade passage. The effects of bleed off-take geometry are presented in this paper by comparing the aerodynamic behavior of a number of generic bleed off-take configurations. Using results from low-speed cascade experiments and three-dimensional numerical calculations, the off-take configurations are compared with respect to the requirement to maximize bleed off-take air pressure and minimize loss generated within the blade passage. The off-take geometry, and especially the introduction of contoured inlet ramp surfaces to guide flow into the off-take for high bleed pressure, has a strong effect on its aerodynamic behavior because it determines the extent to which flow within the off-take is coupled to the primary flow through the blade passage. In this paper, the off-take configurations that give the highest bleed pressure generally cause the highest levels of loss in the blade passage.

1.
Leishman
,
B. A.
,
Cumpsty
,
N. A.
, and
Denton
,
J. D.
, 2007, “
Effects of Bleed Rate and Endwall Location on the Aerodynamic Behavior of a Circular Hole Bleed Off-Take
,”
ASME J. Turbomach.
0889-504X
129
, pp.
645
658
.
2.
Mossman
,
E. A.
, and
Randall
,
L. M.
, 1948, “
An Experimental Investigation of the Design Variables for NACA Submerged Duct Entrances
,” NACA Research Memorandum, No. RM A7130.
3.
Dennard
,
J. S.
, 1957, “
A Transonic Investigation of the Mass-Flow and Pressure Recovery Characteristics of Several Types of Auxiliary Air Inlets
,” NACA Research Memorandum, No. RM L57B07.
4.
Young
,
C.
and
Snowsill
,
G. D.
, 2002, “
CFD Optimization of Cooling Air Off-Take Passages Within Rotor Cavities
,” ASME Paper No. GT-2002–30480.
5.
Dawes
,
W. N.
, 1993, “
The Practical Application of Solution-Adaption to the Numerical Simulation of Complex Turbomachinery Problems
,”
Prog. Aerosp. Sci.
0376-0421
29
, pp.
221
269
.
6.
Leishman
,
B. A.
, 2003, “
The Aerodynamic Behaviour and Design of Compressor Bleed Slots
,” Ph.D. dissertation, University of Cambridge, Cambridge, UK.
You do not currently have access to this content.