Covers the fundamentals of heat transfer, focusing on radiation, conduction, and convection, including boundary layers and Nusselt number.
Explores the fundamentals of heat transfer, including radiation, convection, and conduction, emphasizing boundary layers and Nusselt numbers.
Explores internal forced convection, covering correlations, laminar and turbulent flow, and practical exercises using Jupyter Notebooks.
Covers the fundamentals of heat transfer, including radiative properties, boundary layer theory, and Prandtl number.
Explores heat transfer modes, emphasizing convection, including forced and natural convection, boundary layers, and heat transfer coefficients.
Explores forced external convection correlations and the procedure for solving convection problems, including the comparison of velocity and thermal boundary layers.
Covers the fundamentals of heat transfer in fluids, focusing on conduction, convection, and thermal equilibrium.
Explores the determination of heat transfer coefficients by convection and the significance of adimensional groups in characterizing convective heat transfer.
Covers the fundamentals of heat transfer, including conduction, convection, and radiation, emphasizing the importance of transport laws.
Explores internal forced convection, covering convection coefficients, velocity profiles, and energy balances in pipes.
Explores the evaporation process of a water pond near the sea on a summer day, covering heat and mass transfer laws, convective heat transfer, and practical exercises.
Covers the fundamentals of heat transfer processes, including convection, conduction, and radiation.
Explores internal heat transfer in laminar flows, focusing on entry lengths, mean temperature, and Nusselt number correlations.
