The LM2500+ gas turbine, rated between 39,000–40,200 shaft horsepower (shp), was introduced for field service in 1998. This growth aero-derivative gas turbine is suitable for a variety of power generation applications, such as co-generation and combined cycle, as well as mechanical drive applications. At the heart of the LM2500+ 25% power increase is an up-rated derivative 17-stage axial compressor. This paper describes the aerodynamic design and development of this high-pressure ratio single-spool compressor for the LM2500+ gas turbine. The compressor is derived by zero-staging the highly efficient and reliable LM2500 compressor to increase the flow by 23% at a pressure ratio of 23.3:1. The aerodynamic efficiency of the compressor is further improved by using three-dimensional, custom-tailored airfoil designs similar to those used in the CF6-80C2 high-pressure compressor. The compressor achieved a peak polytropic efficiency above 91%, meeting all its operability objectives. The technical requirements and overall aerodynamic design features of the compressor are presented first. Next, the zero stage match point selection is described and the procedure used to set up the vector diagrams using a through-flow code with secondary flow and mixing is outlined. Detailed design results for the new transonic airfoils in the compressor using three-dimensional viscous analysis are presented. The compressor instrumentation and performance test results are discussed. The performance of the zero stage is separated from that of the baseline compressor with the CF6-80C2 airfoils to show the improvement in efficiency with the new airfoils.

1.
Scalzo, A., and Mori, Y., 1988, “A New 150 MW High Efficiency Heavy Duty Combustion Turbine,” ASME, Paper No. 88-GT-162.
2.
Kashiwabara, Y., Katoh, Y., Ishii, H., Hattori, T., Matsura, Y., and Sasada, T., 1990, “Developments Leading to an Axial Flow Compressor for a 25MW Class High Efficiency Gas Turbine,” ASME, Paper No. 90-GT-238.
3.
Sehra, A., Bettner, J., and Cohn, A., 1991, “
Design of a High Performance Axial Compressor for Utility Gas Turbine,” ASME, Paper No. 91-GT-145.
4.
Smed, J., Pisz, F., Kain, J., Yamaguchi, N., Umemura, S., 1991, “501F Compressor Development Program,” ASME, Paper No. 91-GT-226.
5.
Janssen, M., Zimmermann, H., Kopper, F., and Richardson, J., 1995, “Application of Aero-Engine Technology to Heavy Duty Gas Turbines,” ASME, Paper No. 95-GT-133.
6.
Stringham, G., Cassem, T., Prince, T., and Yeung, P., 1998, “Design and Development of a Nine Stage Axial Flow Compressor for Industrial Gas Turbines,” ASME, Paper No. 98-GT-140.
7.
Farmer
,
R.
, 1994, “GE Launches LM2500+ Rated at 39 MW and 38% Thermal Efficiency,” Gas Turbine World, May/June 1994, pp. 24–32.
8.
Valenti
,
M.
, 1998, “Luxury Liners Go Green,” ASME Mechanical Engineering, July, pp. 72–73.
9.
Klapproth, J. F., Miller, M. L., and Parker, D. E., 1979, “Aerodynamic Development and Performance of the CF6-6/LM2500 Compressor,”AIAA, Paper No. 79-7030.
10.
Eisenberg, B., 1993, “Development of a New Front Stage for an Industrial Axial Flow Compressor,” ASME, Paper No. 93-GT-327.
11.
Katoh, Y., Kashiwabara, Y., Ishii, H., Tsuda, Y., and Yanagida, M., 1993, “Development of a Transonic Front Stage of an Axial Flow Compressor for Industrial Gas Turbines,” ASME, Paper No. 93-GT-304.
12.
Van Leuven, V., 1994, “Solar Turbines Incorporated Taurus 60 Gas Turbine Development,” ASME, Paper No. 94-GT-115.
13.
Rocha, G., Saadatmand, M., and Bolander, G., 1995, “Development of the Taurus 70 Industrial Gas Turbine,” ASME, Paper No. 95-GT-411.
14.
Koch, C. C., 1981, “Stalling Pressure Rise Capacity of Axial Flow Compressor Stages,” ASME Journal of Engineering for Power, October 1981.
15.
Koch, C. C., and Smith, L. H., 1975, “Loss Sources and Magnitudes in Axial Flow Compressors,” GE Aircraft Engines Technical, Report No. R75AEG344.
16.
Adkins
,
G. G.
, and
Smith
,
L. H.
,
1982
, “
Spanwise Mixing in Axial Flow Turbomachines
,”
ASME Journal of Engineering for Power
,
104
, pp.
97
110
.
17.
Jennions
,
I. K.
, and
Turner
,
M. G.
,
1993
, “
Three-Dimensional Navier Stokes Computations of Transonic Fan Flow Using an Explicit Flow Solver and Implicit k-e Solver
,”
ASME Journal of Turbomachinery
,
115
, pp.
261
272
.
18.
Wadia
,
A. R.
, and
Law
,
C. H.
,
1993
, “
Low Aspect Ratio Transonic Rotors: Part 2-Influence of Location of Maximum Thickness on Transonic Compressor Performance
,”
ASME Journal of Turbomachinery
,
115
, pp.
226
239
.
19.
Wadia
,
A. R.
, and
Copenhaver
,
W. W.
,
1996
, “
An Investigation of the Effect of Cascade Area Ratios on Transonic Compressor Performance
,”
ASME Journal of Turbomachinery
,
118
, October 1996, pp.
760
770
.
20.
Wadia
,
A. R.
, and
Beacher
,
B. F.
,
1990
, “
Three-Dimensional Relief in Turbomachinery Blading
,”
ASME Journal of Turbomachinery
,
12
, No.
4
, pp.
587
598
.
21.
Wisler
,
D. C.
,
1985
, “
Loss Reduction in Axial-Flow Compressors Through Low Speed Model Testing
,”
ASME Journal of Engineering for Gas Turbines and Power
,
107
, pp.
354
363
.
22.
Dunavant, J. C., “Cascade Investigation of a Related Series of 6 Percent Thick Guide Vane Profile and Design Charts,” NACA-TN-3959.
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