Finite Element Method - ANSYS Classic
FSI-ZSY-AAcad. year: 2019/2020
Solving problems in mechanics of the continuum. Variational formulation of FEM. Algorithm of FEM. Basic equation and its solution. Finite element types. Convergence and error estimation. Solving nonlinear problems. ANSYS Classic software system - solving of practical problems. User interface, preprocessing - modelling of geometry, discretization, solution, postprocessing - presentation and analysis of results.
Nabízen zahradničním studentům
Learning outcomes of the course unit
The students will understand the basics of the finite-element method especially with the emphasis placed on practical applications. Students will be able to provide stuctural analysis using finite element method.
Knowledge in area of solid mechanics, mathematics, numerical methods, machine design and CAD systems.
Recommended optional programme components
Recommended or required reading
Planned learning activities and teaching methods
The course is taught through lectures explaining the basic principles and theory of the discipline. Exercises are focused on practical topics presented in lectures.
Assesment methods and criteria linked to learning outcomes
Graded course-unit credit is awarded on the following conditions: active participation in the seminars, passing the final test (8th week) based on finite element method theory.
Language of instruction
The objective of the course is to make students familiar with the fundamentals of finite element method (FEM) and computational modelling of mechanical problems. The education is focused on modelling in ANSYS Classic software system, which is wide-spread in companies, universities, and research centers.
Specification of controlled education, way of implementation and compensation for absences
Attendance at lectures is recommended; attendance at practicals is obligatory and checked by the lecturer. One excused absence can be tolerated without compensation. In case of longer absence, compensation of missed lessons depends on the instructions of course supervisor.
Type of course unit
5 hours, compulsory
Teacher / Lecturer
1. Introduction to finite element method. Basic terms and basic quantities in Strength of materials. Variational approach of Lagrange. Ritz method, FEM based on variational approach.
2. Ilustration of FEM on 1D problem. Equilibrium equations in FEM. Link elements. Beam elements.
3. Solid elements - introduction, linear tetrahedral elements.
Solid elements - isoparametric elements; element type selection, free and mapped mesh, discretization of load.
4. Direct and iterative solvers in FEM. Shell elements.
5. Nonlinear problems I. - contact analysis. Nonlinear problems II. - geometrical and material nonlinearity. Convergence and error estimation. Adaptive mesh (h-method, p-method).
30 hours, compulsory
Teacher / Lecturer
1. Introductory example - model of tensile test.
2. Modelling of 2D geometry.
3. Modelling of 3D geometry.
4. Link elements transferring tension and compression (2D and 3D analysis).
5. Beam elements (2D and 3D analysis). Gravity load.
6. Stress and strain analysis in 2D.
7. Stress and strain analysis in 3D.
8. Stress and strain analysis of machine part with notch.
9. Shell elements, stress analysis of T-shape pipeline (thin-walled construction).
10. Contact of the ball with flat bottom - creation of computational model.
11. Contact of the ball with flat bottom - solution and analysis of results.
12. Advanced contact analyses (e.g. press-fit joint). Principles of APDL.
eLearning: currently opened course