Curriculum
1. Software of DesignModeler. Basic menus and pull-down menu of DesignModeler. Presentation of results of CFD analysis of fuel combustion problems based on presented works published on the Internet.
2. Generating of the 3D geometry in DesignModeler. Tools to edit imported 3D geometry in DesignModeler. Introducing SpaceClaim to create geometry.
3. Software for creation of the computer grid in ANSYS Meshing, methods for generation of grid, 3D elements. Criteria of computer grid quality evaluation, boundary layer types, grid adaptation.
4. Numerical solution of first order differential equations, integral method, finite volume method, simple and simplec methods, interpolation scheme, convergence (residuals, uderrelax). Application of various elements on 3D geometry, evaluation of computer grid quality, creation of different types of boundary layers, export of computer grid to ANSYS Fluent.
5. Physical properties, mass transfer (Fick's law), conduction heat transfer (Fourier's law), mass and momentum transfer (convection), convection and conduction heat transfer.
6. Types of boundary conditions for compressible and incompressible flow. Definition of physical properties of gaseous mixture (constant, functional dependence on temperature, kinetic theory of gas) and mixtures, characteristics of terms: concentration, mass fraction, volume fraction.
7. Turbulence, compressible flow, N-S equation, continuity equation, Reynolds equation and rules, time averaging, Boussinesq hypothesis.
8. Energy equations for incompressible and compressible flow, heat transfer through the wall (thin wall), heat transfer through the wall of real thickness (SOLID), types of boundary conditions for walls, modeling near the wall, wall functions.
9. Transport equations for mass fractions, definition of diffusion flux and source term due to chemical reaction, definition of mixture and calculation of physical properties of mixture.
10. Flow of gases with chemical reaction and heat transfer and radiation, energy equation, models of combustion of gaseous phases, definition of kinetics of combustion process using Arhenius equation (pre-exponential factor, activation energy).
11. Flow with solid particles and drops, trajectory, definition of discrete phase, interaction with continuous phase, phase change, mathematical modeling of solid particles combustion.
12. Multiphase flow, characteristics of mathematical models VOF, Mixture, Euler, definition of individual phases, definition of cavitation by multiphase mathematical model, physical properties of phases.
13. Mathematical approaches to combustion of solid fuels, problems of defining a mathematical model of lump wood combustion in fireplace stoves, mathematical modeling of low-temperature coal oxidation.
14. Solving the problems of pulverized coal combustion in the fall tube, evaluation of mathematical approaches and comparison with the experiment.
1. Software of DesignModeler. Basic menus and pull-down menu of DesignModeler. Presentation of results of CFD analysis of fuel combustion problems based on presented works published on the Internet.
2. Generating of the 3D geometry in DesignModeler. Tools to edit imported 3D geometry in DesignModeler. Introducing SpaceClaim to create geometry.
3. Software for creation of the computer grid in ANSYS Meshing, methods for generation of grid, 3D elements. Criteria of computer grid quality evaluation, boundary layer types, grid adaptation.
4. Numerical solution of first order differential equations, integral method, finite volume method, simple and simplec methods, interpolation scheme, convergence (residuals, uderrelax). Application of various elements on 3D geometry, evaluation of computer grid quality, creation of different types of boundary layers, export of computer grid to ANSYS Fluent.
5. Physical properties, mass transfer (Fick's law), conduction heat transfer (Fourier's law), mass and momentum transfer (convection), convection and conduction heat transfer.
6. Types of boundary conditions for compressible and incompressible flow. Definition of physical properties of gaseous mixture (constant, functional dependence on temperature, kinetic theory of gas) and mixtures, characteristics of terms: concentration, mass fraction, volume fraction.
7. Turbulence, compressible flow, N-S equation, continuity equation, Reynolds equation and rules, time averaging, Boussinesq hypothesis.
8. Energy equations for incompressible and compressible flow, heat transfer through the wall (thin wall), heat transfer through the wall of real thickness (SOLID), types of boundary conditions for walls, modeling near the wall, wall functions.
9. Transport equations for mass fractions, definition of diffusion flux and source term due to chemical reaction, definition of mixture and calculation of physical properties of mixture.
10. Flow of gases with chemical reaction and heat transfer and radiation, energy equation, models of combustion of gaseous phases, definition of kinetics of combustion process using Arhenius equation (pre-exponential factor, activation energy).
11. Flow with solid particles and drops, trajectory, definition of discrete phase, interaction with continuous phase, phase change, mathematical modeling of solid particles combustion.
12. Multiphase flow, characteristics of mathematical models VOF, Mixture, Euler, definition of individual phases, definition of cavitation by multiphase mathematical model, physical properties of phases.
13. Mathematical approaches to combustion of solid fuels, problems of defining a mathematical model of lump wood combustion in fireplace stoves, mathematical modeling of low-temperature coal oxidation.
14. Solving the problems of pulverized coal combustion in the fall tube, evaluation of mathematical approaches and comparison with the experiment.