Direct numerical simulation of air-cooled and air-heated channels

Conference paper (2024)

Authors

D. Modesti Aerodynamics - Aerospace Engineering

Sergio Pirozzoli Sapienza University of Rome

Research Group

Aerodynamics (Aerospace Engineering) (TU Delft)

Direct numerical simulation Forced thermal convection Forced-air convection Variable-fluid properties

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http://resolver.tudelft.nl/uuid:f59aa23f-f9f3-4a1b-bd18-b24d19bc9dda

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Published Date

2024

Language

English

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Faculty

Aerospace Engineering

Department

Flow Physics and Technology

Research Group

Aerodynamics

Abstract

We develop a theoretical framework for predicting friction and heat transfer coefficients in variable-properties forced-air convection, as typical of turbine blade cooling. To do this, we borrow concepts from high-speed wall turbulence, also featuring large temperature and density variations. Using the mean momentum balance and mean thermal balance equations we develop integral transformations that account for the effect of the variable fluid properties, and apply the inverse transformations to calculate the friction and heat transfer coefficients. The proposed theory is validated using a direct numerical simulation dataset spanning both heating and cooling conditions, and the predicted friction and heat transfer coefficients match DNS data with 1–2% accuracy.