Studies of Gas Turbine Heat Transfer Airfoil Surfaces and End-Wall Cooling Effects

Abstract

Understanding and prediction of the heat transfer in a turbine is dependent first on understanding the complex three dimensional flow that occurs around a blade. In a turbine passage there are complex (interacting) vortices, significant variation in surface curvature, flow separation, transition from laminar to turbulent flow and perhaps relaminarization, and the influence of high turbulence level in the free stream flow. Heat or mass transfer measurements, aside from providing the needed design information, can also tell us a great deal about the flow. The transport of heat or mass has been used to detect characteristics of flow which were not readily detectable by other means. Modeling for computation of hte flow and heat transfer, also, require knowledge of the flow as well as transport data to check the validity of models and their accuracy.

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Document Details

Document Type
Technical Report
Publication Date
Jul 01, 1989
Accession Number
ADA212451

Entities

People

  • E. R. Eckert
  • R. J. Goldstein
  • S. V. Patankar
  • Terrence W. Simon

Organizations

  • University of Minnesota

Tags

Communities of Interest

  • Energy and Power Technologies
  • Materials and Manufacturing Processes

DTIC Thesaurus Topics

  • Boundary Layer
  • Computational Fluid Dynamics
  • Flow Fields
  • Flow Visualization
  • Fluid Dynamics
  • Fluid Flow
  • Fluid Mechanics
  • Gas Turbines
  • Geometry
  • Heat Transfer
  • Hot Wire Anemometers
  • Mechanics
  • Test Facilities
  • Three Dimensional
  • Turbines
  • Turbulent Flow
  • Turbulent Mixing

Fields of Study

  • Physics

Readers

  • Fluid Mechanics and Fluid Dynamics.
  • Systems Analysis and Design
  • Thermal Physics or Thermal Science.