Computational Fluid Dynamics Analysis of a Steam Power Plant Low-Pressure Turbine Downward Exhaust Hood-Reference-Cited by-同舟云学术

Computational Fluid Dynamics Analysis of a Steam Power Plant Low-Pressure Turbine Downward Exhaust Hood

Published:1996-01-01 Issue:1 Volume:118 Page:214-224
ISSN:0742-4795
Container-title:Journal of Engineering for Gas Turbines and Power
language:en
Short-container-title:

Author:

Tindell R. H.¹,Alston T. M.¹,Sarro C. A.²,Stegmann G. C.²,Gray L.³,Davids J.³

Affiliation:

1. Northrop-Grumman Corporation, Advanced Technology & Development Center, Bethpage, NY 11714

2. Consolidated Edison Company of New York, Inc., New York, NY 10003

3. Westinghouse Electric Corporation, Orlando, FL 39826

Abstract

Computational fluid dynamics (CFD) methods are applied to the analysis of a low-pressure turbine exhaust hood at a typical steam power generating station. A Navier-Stokes solver, capable of modeling all the viscous terms, in a Reynolds-averaged formulation, was used. The work had two major goals. The first was to develop a comprehensive understanding of the complex three-dimensional flow fields that exist in the exhaust hood at representative operating conditions. The second was to evaluate the relative benefits of a flow guide modification to optimize performance at a selected operating condition. Also, the influence of simulated turbine discharge characteristics, relative to uniform hood entrance conditions, was evaluated. The calculations show several interesting and possibly unique results. They support use of an integrated approach to the design of turbine exhaust stage blading and hood geometry for optimum efficiency.

Publisher

ASME International

Subject

Mechanical Engineering,Energy Engineering and Power Technology,Aerospace Engineering,Fuel Technology,Nuclear Energy and Engineering

Link

http://asmedigitalcollection.asme.org/gasturbinespower/article-pdf/118/1/214/5536065/214_1.pdf

Reference8 articles.

1. Baldwin, B. S., and Lomax, H., 1978, “Thin Layer Approximation and Algebraic Model for Separated Turbulent Flows,” AIAA Paper No. 78-257.

2. Gray, L., et al., 1989, “Technical Considerations in Optimizing Blade-Exhaust Hood Performance for Low Pressure Steam Turbines,” in: Latest Advances in Steam Turbine Design, Blading, Repairs, Condition, Assessment, and Condenser Interaction, D. M. Rasmussen, ed., ASME PWR-Vol. 7.

3. Owczarek, J. A., and Warnock, A. S., 1989, “Improvement of a Low Pressure Turbine Exhaust Flow,” EP 86-36, Empire State Electric Energy Research Cor-poration, Dec.

4. Owczarek, J. A., Warnock, A. S., and Malik, P., 1989, “A Low Pressure Turbine Exhaust End Flow Model Study,” in: Latest Advances in Steam Turbine Design, Blading, Repairs, Condition, Assessment, and Condenser Interaction, D. M. Rasmussen, ed., ASME PWR-Vol. 7, pp. 77–88.

5. Phares, W. J., et al., 1986, “Application of Computational Fluid Dynamics to Test Facility and Experiment Design,” AIAA Paper 86-1733.

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