Students are able to

• apply advanced knowledge in the treatment and solution of problems arising from heat and mass transportation.
• solve typical modelling problems analytically and numerically.
• examine selected problems of the FE method, compared with the analytical methods and metrological results.

MBLB-Math, MBLB-KoMe

• Stationary and transient heat transfer
• Extended surfaces
• Radiation
• Thermofluid dynamics
• Navier-Stokes equation
• Mass transfer
• Diffusion equations
• Discussion of analytical and numerical solutions
• Discretization Methods: Finite Differences, Finite Elements
• Experimental Validation

F. P. Incopera, D.P deWitt: Fundamentals of Heat and Mass Transfer, Wiley (2019)
F. Kreith, R. M. Manglik, M. S. Bohn: Principles of Heat Transfer, Cengage Learning (2011)
R. Marek, K. Nitsche: Praxis der Wärmeübertragung, Hanser (2019)
Ph. M. Gerhart, A.L. Gerhart, J.I. Hochstein: Munson, Young and Okiishi´s Fundamentals of Fluid Mechanics, Wiley (2018)
C. Borgnakke, R.E. Sonntag: Fundamentals of Thermodynamics, Wiley (2020)
E. Laurien, H. Oertel: Numerische Strömungsmechanik, Springer (2018)
S. Lecheler: Computational Fluid Dynamics, Springer (2022)
A. Stoffel: Finite Elemente und Wärmeleitung, Wiley-VCH (1992)
T. Cebeci, P. Bradshaw: Physical and Computational Aspects of Convective Heat Transfer, Springer (2013)

Journals:
Heat and Mass Transfer
Heat transfer Engineering
Journal of Heat Transfer

Lecture, discussion, exercises and case studies

Integrated module examination
Immanent assessment type: participation & written final examination