Students should gain theoretical and professional knowledge that will enable them to independently recognize and solve a complex stationary and transient heat transfer problems in area conjugate heat and mass transfer in porous materials, problem of transient heat transfer with phase change - melting and solidification and boiling and condensation, heat transfer in laminar and turbulent flow and radiation heat exchange between flue gases (products of combustion) and solid body.

After successful completion of this course students should be able to: 1) describe and explain the physical essence and mechanisms and express the hypotheses and laws that describe the complex processes of heat transfer 2) calculate the temperature field and heat flow in porous materials 3) calculate the temperature field and heat flow in materials during process of melting and solidification 4) describe and explain the boundary layer theory and heat transfer in turbulent flow 5) describe and explain the physical essence and the hypothesis of analogies among heat, mass, and momentum transfer 6) calculate the temperature field and heat flow in materials during process of boiling and condensation 7) calculate the radiation heat flow between flue gases and solid body

1. Analytical methods for solving the problem of unsteady molecular transfer of energy and substance through the homogeneous isotropic or anisotropic materials 2. Analytical methods for solving the problem of heat transfer in porous materials 3. Analytical methods for solving the problem of not steady heat conduction with the change of the aggregate state - the process of melting and solidification 4. Boundary layer theory. Heat transfer in turbulent flow 5. Analogy among heat, mass, and momentum transfer 6. Analytical methods for solving the problem of heat transfer with phase change - boiling and condensation 7. Analytical methods for solving the problem of coupled heat and mass transfer problems 8. Thermal radiation of gases and vapors. Radiation exchange between flue gases with and without solid particles and surface of solid body.

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Desirable, passed exams: Basic heat and mass transfer and Heat transfer

Total assigned hours: 65

New material: 40
Elaboration and examples (recapitulation): 10

Auditory exercises: 0
Laboratory exercises: 0
Calculation tasks: 0
Seminar paper: 0
Project: 0
Consultations: 0
Discussion/workshop: 0
Research study work: 0

Review and grading of calculation tasks: 0
Review and grading of lab reports: 0
Review and grading of seminar papers: 0
Review and grading of the project: 0
Test: 0
Test: 0
Final exam: 15

Activity during lectures: 0
Test/test: 0
Laboratory practice: 0
Calculation tasks: 0
Seminar paper: 50
Project: 0
Final exam: 50
Requirement for taking the exam (required number of points): 40

Milincic, D., Vasiljevic, B., Djordjevic, R.: Heat Transfer Problems, Faculty of Mechanical Engineering of University of Belgrade, Belgrade, 1991.; Milincic, D.: Heat transfer, Naucna knjiga, Belgrade, 1989.; Incropera, F., DeWit, D., Bergman, T, Lavine, A: Introduction to Heat Transfer, Wiley, 5th edition, 912 pages, 2006.; Cengel, Y.: Heat Transfer A Practical Approach, McGraw - Hill; 2nd edition 1024 pages, 2003; Cengel, Y., Ghajar, A: Heat and Mass Transfer: Fundamentals and Applications + EES DVD for Heat and Mass Transfer, McGraw-Hill Science/Engineering/Math; 4 edition, 924 pages, 2010.