Explores forced external convection correlations and the procedure for solving convection problems, including the comparison of velocity and thermal boundary layers.
Covers exercises on heat and mass transfer, including multimodal heat transfer and transient conduction.
Explores internal forced convection, covering convection coefficients, velocity profiles, and energy balances in pipes.
Explores turbulence characteristics, simulation methods, and modeling challenges, providing guidelines for choosing and validating turbulence models.
Explores condensation principles, including fluid motion factors and correlations for convection coefficients in different scenarios.
Covers exercises on surface radiative properties, including spectral absorptivity, reflectivity, emissivity, and temperature changes.
Focuses on velocity boundary layer equations in laminar flow and covers mass and momentum conservation, Navier-Stokes equations, and the Reynolds number.
Covers the fundamentals of heat transfer, focusing on radiation, conduction, and convection, including boundary layers and Nusselt number.
Explores internal forced convection, covering correlations, laminar and turbulent flow, and practical exercises using Jupyter Notebooks.
Explores the fundamentals of heat transfer, including radiation, convection, and conduction, emphasizing boundary layers and Nusselt numbers.
Covers the fundamentals of free convection and correlations for heat transfer between a solid and a fluid in motion at different temperatures.
Explores heat transfer modes, emphasizing convection, including forced and natural convection, boundary layers, and heat transfer coefficients.
