Traditionally, engine performance has been simulated based on nondimensional maps for compressors and turbines. Component characteristic maps assume by default a given state of inlet conditions that cannot be easily altered in order to simulate two- or three-dimensional flow phenomena. Inlet flow distortion, for example, is usually simulated by applying empirical correction factors and modifiers to default component characteristics. Alternatively, the parallel compressor theory may be applied. The accuracy of the above methods has been rather questionable over the years since they are unable to capture in sufficient fidelity component-level, complex physical processes and analyze them in the context of the whole engine performance. The technique described in this paper integrates a zero-dimensional (nondimensional) gas turbine modelling and performance simulation system and a two-dimensional, streamline curvature compressor software. The two-dimensional compressor software can fully define the characteristics of any compressor at several operating conditions and is subsequently used in the zero-dimensional cycle analysis to provide a more accurate, physics-based estimate of compressor performance under clean and distorted inlet conditions, replacing the default compressor maps. The high-fidelity, two-dimensional compressor component communicates with the lower fidelity cycle via a fully automatic and iterative process for the determination of the correct operating point. This manuscript firstly gives a brief overview of the development, validation, and integration of the two-dimensional, streamline curvature compressor software with the low-fidelity cycle code. It also discusses the relative changes in the performance of a two-stage, experimental compressor with different types of radial pressure distortion obtained by running the two-dimensional streamline curvature compressor software independently. Moreover, the performance of a notional engine model, utilizing the coupled, two-dimensional compressor, under distorted conditions is discussed in detail and compared against the engine performance under clean conditions. In the cases examined, the analysis carried out by this study demonstrated relative changes in the simulated engine performance larger than 1%. This analysis proves the potential of the simulation strategy presented in this paper to investigate relevant physical processes occurring in an engine component in more detail, and to assess the effects of various isolated flow phenomena on overall engine performance in a timely and affordable manner. Moreover, in contrast to commercial computational fluid dynamics tools, this simulation strategy allows in-house empiricism and expertise to be incorporated in the flow-field calculations in the form of deviation and loss models.

1.
Pachidis
,
V.
,
Pilidis
,
P.
,
Guindeuil
,
G.
,
Kalfas
,
A.
, and
Templalexis
,
I.
, 2005, “
A Partially Integrated Approach to Component Zooming Using Computational Fluid Dynamics
,” ASME Paper No. GT2005-68457.
2.
Pachidis
,
V.
,
Pilidis
,
P.
,
Talhouarn
,
F.
,
Kalfas
,
A.
, and
Templalexis
,
I.
, 2005, “
A Fully Integrated Approach to Component Zooming Using Computational Fluid Dynamics
,” ASME Paper No. GT2005-68458.
3.
Turner
,
M. G.
,
Reed
,
J. A.
,
Ryder
,
R.
, and
Veres
,
J. P.
, 2004, “
Multi-fidelity Simulation of a Turbofan Engine With Results Zoomed Into Mini-maps for a Zero-d Cycle Simulation
,” ASME Paper No. GT2004-53956.
4.
Reed
,
J. A.
, and
Afjeh
,
A. A.
, 1994, “
Development of an Interactive Graphical Propulsion System Simulator
,” 30th AIAA/ASIVIEISAE/ASEE Joint Propulsion Conference, University of Toledo, AIAA Paper No. 94-3216, June.
5.
Reed
,
J. A.
, and
Afjeh
,
A. A.
, 1994, “
Distributed and Parallel Programming in Support of Zooming in Numerical Propulsion System Simulation
,” NASA Proceeding of Symposium on Applications of Parallel and Distributed Computing, Columbus, OH, April.
6.
Reed
,
J. A.
, and
Afjeh
,
A. A.
, 1995, “
An Interactive Graphical System for Engine Component Zooming in a Numerical Propulsion System Simulation
,” University of Toledo, 33rd Aerospace Sciences Meeting and Exhibit, A1AA Paper No. 95-0118, January.
7.
Reed
,
J. A.
, and
Afjeh
,
A. A.
, 1997, “
A Comparative Study of High and Low Fidelity Fan Models for Turbofan Engine System Simulation
,”
Proceedings of the IASTED International Conference on Applied Modelling and Simulation
, Banff, Canada, July.
8.
Smith
,
L. H.
, 1994, “
NASA/GE Fan and Compressor Research Accomplishments
,”
ASME J. Turbomach.
0889-504X,
116
(
4
), pp.
554
568
.
9.
Wu
,
C., H.
, 1952, “
A General Through-Flow Theory of Three-Dimensional Flow in Subsonic and Supersonic Turbomachines of Axial-, Radial-, and Mixed-Flow Types
,” NASA Report No. TN2604.
10.
Novak
,
R. A.
, 1967, “
Streamline Curvature Computing Procedures for Fluid-Flow Problems
,”
ASME J. Eng. Power
0022-0825,
89
, pp.
478
490
.
11.
Jansen
,
W.
, and
Moffatt
,
W. C.
, 1967, “
The Off-Design Analysis of Axial Flow Compressors
,”
ASME J. Eng. Power
0022-0825,
89
, pp.
453
462
.
12.
Denton
,
J. D.
, 1978, “
Throughflow Calculations for Transonic Axial Flow Turbines
,”
ASME J. Eng. Power
0022-0825,
100
, pp.
212
218
.
13.
Jennions
,
I. K.
, and
Stow
,
P.
, 1985, “
The Quasi-Three-Dimensional Turbomachinery Blade Design System, Part I: Throughflow Analysis, Part II: Computerized System
,”
Trans. ASME: J. Eng. Gas Turbines Power
0742-4795,
107
, pp.
308
316
.
14.
Jennions
,
I. K.
, and
Stow
,
P.
, 1986, “
The Importance of Circumferential Non-uniformities in a Passage Averaged Quasi-Three-Dimensional Turbomachinery Design System
,”
Trans. ASME: J. Eng. Gas Turbines Power
0742-4795
108
, pp.
240
245
.
15.
Barbosa
,
J. R.
, 1987, “
A Streamline Curvature Computer Program for Axial Compressor Performance Prediction
,” Ph.D thesis, Vol. 1, Cranfield Institute of Technology, School of Mechanical Engineering.
16.
Pachidis
,
V.
, 2004, “
Gas Turbine Simulation – PYTHIA Workshop Guide
,” Part I and II, Cranfield University, Department of Power, Propulsion and Aerospace Engineering, ASME/IGTI Aero Engine Life Management Conference, London, March.
17.
Palmer
,
J. R.
, 1990, “
The TURBOMATCH Scheme For Aero/Industrial Gas Turbine Engine Design Point/Off Design Performance Calculation
,” SME, Thermal Power Group, Cranfield University.
18.
Pachidis
,
V.
, 2006, “
Gas Turbine Advanced Performance Simulation
,” Ph.D thesis, Cranfield University, School of Engineering, January.
19.
Urasek
,
D. C.
,
Gorell
,
W. T.
, and
Cunnan
,
W. S.
, 1979, “
Performance of Two-Stage Fan Having Low-Aspect-Ratio, First Stage Rotor Blading
,” NASA Technical Paper No. 1493.
20.
Schmidt
,
J. F.
, and
Ruggeri
,
R. S.
, 1978, “
Performance With and Without Inlet Radial Distortion of a Transonic Fan Stage Designed for Reduced Loading in the Tip Region
,” NASA Technical Paper No. 1294, August.
You do not currently have access to this content.