1. Basic laws and analogies of transmission phenomena.
2. Momentum transfer, Euler, Navier-Stokes, and Bernoulli equations for three-dimensional arrangement, Newtonian and non-Newtonian fluids.
3. Energy transfer, shell balance. Fourier-Kirchhoff equation, selection of initial and boundary conditions.
4. Mass transfer, I. and II Fick's law of diffusion
5. Theory of similarity and modeling, similarity theorems. Basic methods of similarity theory, analysis of momentum, energy, and mass transfer. Mathematical modeling of transfer phenomena, a mathematical three-dimensional model, and solving calculations using the Fluent model. Visibility of transmission phenomena.
6. Differential equations of heat conduction, non-stationary heat conduction - analytical solution, conditions of uniqueness. Numerical methods for unsteady one-dimensional heat conduction.
7. Numerical multidimensional solution of non-stationary heat transfer, explicit and implicit methods.
8. Theory of similarity in thermal convection, general forms of criteria equations. Natural and forced convection.
9. Heat transfer at boiling, types and modes of boiling. Heat transfer during condensation. Phase interface transmission phenomena.
10. Heat transfer by radiation between solid bodies separated by a perfectly flowing environment, basic terms, radiation of an absolutely black body, gray body, radiation of real bodies, closed system.
11. Heat transfer between bodies arbitrarily placed in space, open system, radiation coefficient.
12. Basic knowledge of thermal radiation of gases and flame, shielding walls, and radiation temperature measurement.
13. Heat exchangers, sorting, brief characteristics, and construction. Basics of heat and hydraulic calculation of recuperative heat exchangers, cross-exchangers, transfer number NTU, and efficiency of exchangers. + Experimental problem - measurement of tube in tube. Convection heat transfer at supersonic speeds.
2. Momentum transfer, Euler, Navier-Stokes, and Bernoulli equations for three-dimensional arrangement, Newtonian and non-Newtonian fluids.
3. Energy transfer, shell balance. Fourier-Kirchhoff equation, selection of initial and boundary conditions.
4. Mass transfer, I. and II Fick's law of diffusion
5. Theory of similarity and modeling, similarity theorems. Basic methods of similarity theory, analysis of momentum, energy, and mass transfer. Mathematical modeling of transfer phenomena, a mathematical three-dimensional model, and solving calculations using the Fluent model. Visibility of transmission phenomena.
6. Differential equations of heat conduction, non-stationary heat conduction - analytical solution, conditions of uniqueness. Numerical methods for unsteady one-dimensional heat conduction.
7. Numerical multidimensional solution of non-stationary heat transfer, explicit and implicit methods.
8. Theory of similarity in thermal convection, general forms of criteria equations. Natural and forced convection.
9. Heat transfer at boiling, types and modes of boiling. Heat transfer during condensation. Phase interface transmission phenomena.
10. Heat transfer by radiation between solid bodies separated by a perfectly flowing environment, basic terms, radiation of an absolutely black body, gray body, radiation of real bodies, closed system.
11. Heat transfer between bodies arbitrarily placed in space, open system, radiation coefficient.
12. Basic knowledge of thermal radiation of gases and flame, shielding walls, and radiation temperature measurement.
13. Heat exchangers, sorting, brief characteristics, and construction. Basics of heat and hydraulic calculation of recuperative heat exchangers, cross-exchangers, transfer number NTU, and efficiency of exchangers. + Experimental problem - measurement of tube in tube. Convection heat transfer at supersonic speeds.