L - Lecture, E - Exercise
1. L.: Introduction, numerical modeling of flow - various commercial systems, Fluent - physical models, turbulence models, methods of solving heat transfer, mass and momentum, commercial systems for the solution of flow, solved examples from the company, department, environmental jobs
E: Working on workstations, Windows, Introduction to Fluent
2. L.: The continuum hypothesis, the physical properties of solids and fluids, dimensionless criteria
E: Creating geometry in ANSYS-meshing, the environment, drawing basic services. Modeling of laminar flow in a 2D geometry, graphical evaluation of results
3. L: Definition of transfer, convection, diffusion, transfer balance equations, boundary conditionsC
E: Creating a sudden expansion geometry, flow methods of networking with a sudden expansion flow cross-section geometry, boundary conditions
4. L: Numerical methods, difference methods, geometry creation, grid, convergence, and the residuals.
E: Grid 2D and 3D, grid control, export to Fluent
5. L: Heat transfer by conduction, boundary conditions, one-dimensional heat conduction, time-dependent solutions.
E.: Modelling of heat conduction in different materials,
6. L: The basic equations of mass transfer of momentum and energy - the continuity equation, Navier-Stokes equations, energy equations, boundary conditions.
E: Time-dependent solution of heat conduction
7. L: Solution of conduction and convection in laminar flow, boundary conditions for thin wall with heat transfer in flow around the plate.
E.: Modelling of laminar flow in a rectangular space, graphical evaluation of results
8. L: Turbulent flow, Reynolds equation and continuity equation, k-eps turbulence model, boundary conditions, wall functions, the influence of network quality on the choice of wall functions, solution of conduction and convection in the turbulent flow around plates
E: Modeling of turbulent flow in a rectangular gap and conduction in the wall, graphical evaluation of results
9. Wrap pipes and pipe wraping with heat transfer
E: Modelling of turbulent flow in the pipe wrap 2D, evaluation of thermal performance, Nusselt number
10. L: Flow across a bundle of tubes arranged in a row and a cross
E: Solution of individual work
11. L: Analysis of heat exchangers, heat output and heat dissipation and performance, methods of calculating the heat exchanger.
E: Solution of individual work
12. L: Solution co-flow and counter-flow heat exchanger
E: Solution of individual work
13. L: Calculation of the heat exchanger of water-air and co- and counter-flow spiral heat exchanger
E: Solution of individual work
14. Consultation
C: Presentation of seminar papers, credit
1. L.: Introduction, numerical modeling of flow - various commercial systems, Fluent - physical models, turbulence models, methods of solving heat transfer, mass and momentum, commercial systems for the solution of flow, solved examples from the company, department, environmental jobs
E: Working on workstations, Windows, Introduction to Fluent
2. L.: The continuum hypothesis, the physical properties of solids and fluids, dimensionless criteria
E: Creating geometry in ANSYS-meshing, the environment, drawing basic services. Modeling of laminar flow in a 2D geometry, graphical evaluation of results
3. L: Definition of transfer, convection, diffusion, transfer balance equations, boundary conditionsC
E: Creating a sudden expansion geometry, flow methods of networking with a sudden expansion flow cross-section geometry, boundary conditions
4. L: Numerical methods, difference methods, geometry creation, grid, convergence, and the residuals.
E: Grid 2D and 3D, grid control, export to Fluent
5. L: Heat transfer by conduction, boundary conditions, one-dimensional heat conduction, time-dependent solutions.
E.: Modelling of heat conduction in different materials,
6. L: The basic equations of mass transfer of momentum and energy - the continuity equation, Navier-Stokes equations, energy equations, boundary conditions.
E: Time-dependent solution of heat conduction
7. L: Solution of conduction and convection in laminar flow, boundary conditions for thin wall with heat transfer in flow around the plate.
E.: Modelling of laminar flow in a rectangular space, graphical evaluation of results
8. L: Turbulent flow, Reynolds equation and continuity equation, k-eps turbulence model, boundary conditions, wall functions, the influence of network quality on the choice of wall functions, solution of conduction and convection in the turbulent flow around plates
E: Modeling of turbulent flow in a rectangular gap and conduction in the wall, graphical evaluation of results
9. Wrap pipes and pipe wraping with heat transfer
E: Modelling of turbulent flow in the pipe wrap 2D, evaluation of thermal performance, Nusselt number
10. L: Flow across a bundle of tubes arranged in a row and a cross
E: Solution of individual work
11. L: Analysis of heat exchangers, heat output and heat dissipation and performance, methods of calculating the heat exchanger.
E: Solution of individual work
12. L: Solution co-flow and counter-flow heat exchanger
E: Solution of individual work
13. L: Calculation of the heat exchanger of water-air and co- and counter-flow spiral heat exchanger
E: Solution of individual work
14. Consultation
C: Presentation of seminar papers, credit