Sage Journals: Discover world-class research

Abstract

Gas turbine blade cooling has major importance in improving the gas turbine cycle performance by an increase in turbine inlet temperature (TIT). Among different cooling techniques available, the convection and film cooling are the most widely used techniques. Studies have shown that transpiration cooling technique uses the coolant more effectively than the film and convection cooling techniques. The present study deals with the performance evaluation of gas turbine cycle with transpiration cooling of gas turbine blades. A comparison has been made using air and steam as cooling mediums. Cycle performance has been evaluated in terms of overall efficiency and specific power. Literature shows that in existing gas turbine blade cooling models the effect of radiation from higher temperature gases is usually neglected. However, the radiation occurs due to presence of high-temperature combustion products primarily comprising of CO₂, NO_x, and H₂O. The present article evaluates the gas cycle performance taking radiation effect into account. A computer code ‘GTANALYS’ has been developed to perform all the computations. The results show that for the given conditions steam appears to be better coolant compared to air. For a TIT of 1700 K and cycle pressure ratio of 32, the steam-cooled cycle efficiency is about 2.58 per cent higher than air-cooled cycle efficiency.

Keywords

gas turbine transpiration cooling cooling with air vis-à-vis steam cycle performance radiation

Get full access to this article

View all access options for this article.

References

Sanjay Singh

Prasad

B. N.

Influence of different means of turbine blade cooling on the thermodynamic performance of combined cycle

Appl. Therm. Eng. 2008 28 2315–2326

Albeirutty

M. H.

Alghamdi

A. S.

Najjar

Y. S.

Heat transfer analysis for a multistage gas turbine using different blade-cooling schemes

Appl. Therm. Eng. 2004 24 563–577

Chiesa

Macchi

A thermodynamic analysis of different options to break 60% electric efficiency in combined cycle power plants

ASME J. Engng Gas Turbines Power 2004 126 770–785

Horlock

J. H.

Watson

D. T.

Jones

T. V.

Limitations on gas turbine performance imposed by large turbine cooling flows

ASME J. Engng Gas Turbines Power 2001 123 487–494

Sanjay Singh

Prasad

B. N.

Thermodynamic modeling and simulation of advanced combined cycle for performance enhancement

Proc. IMechE, Part A: J. Power and Energy 2008 222 541–555 DOI: 10.1243/ 09576509JPE593

Sanjay Singh

Prasad

B. N.

Energy and exergy analysis of steam cooled reheat gas–steam combined cycle

Appl. Therm. Eng. 2007 27 2779–2790

El-Masri

M. A.

Pourkey

Prediction of cooling flow requirements for advanced utility gas turbines Part 1: Analysis and scaling of the effectiveness curve 1986 In Proceedings of the ASME, Winter Annual MeetingCalifornia 1–9

Kumar

Singh

Thermodynamic evaluation of different gas turbine blade cooling techniques 2008 In Proceedings of the IEEE Xplore Conference Proceedings – Second International Conference on Thermal issues in emerging technologies, ThETA ‘08’ 2008 Cairo, Egypt 237–244 DOI: 10.1109/THETA.5167172

Eckert

E. R. G.

Livingood John

N. B.

Comparison of effectiveness of convection, transpiration and film cooling methods with air as coolant 1953 593–609 Report, NACA

10.

Lanzafame

Messina

A new method for the calculation of gases enthalpy 318–328 AIAA-2000–2851

11.

12.

Young

J. B.

Horlock

J. H.

Defining the efficiency of a cooled turbine

ASME J. Turbomach 2006 128 658–667

13.

Torbidoni

Massardo

A. F.

Analytical blade row cooling model for innovative gas turbine cycle evaluations supported by semi-empirical air-cooled blade data

ASME J. Engng Gas Turbines Power 2004 126 498–506

14.

Thermodynamic performance evaluation of gas turbine cycle with transpiration cooling of blades using air vis-à-vis steam

Abstract

Abstract

Keywords

Get full access to this article

References