FEM in Engineering Computations (FSI-RIV)
| Academic year 2019/2020 |
| Supervisor: | prof. Ing. Jindřich Petruška, CSc. | |||
| Supervising institute: | ÚMTMB | |||
| Teaching language: | Czech | |||
| Aims of the course unit: | ||||
| Aim of the course is to present numerical solution of problems of Structural and Continuum Mechanics by Finite Element Method and to give a general view of the possibilities of commercial FE packages. |
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| Learning outcomes and competences: | ||||
| Students learn how to formulate appropriate computational models of typical problems of applied mechanics. They will become experienced in preparation, running and postprocessing of FE models and able to use any of the commercial FE packages after only a short introductory training. |
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| Prerequisites: | ||||
| Matrix notation, linear algebra, function of one and more variables, calculus, differential equations, elementary dynamics, elasticity and thermal conduction. | ||||
| Course contents: | ||||
| The course presents an introduction to selected numerical methods in Continuum Mechanics (finite difference method, boundary element method) and, in particular, a more detailed discourse of the Finite Element Method. The relation to Ritz method is explained, algorithm of the FEM is presented together with the basic theory and terminology (discretisation of continuum, types of elements, shape functions, element and global matrices of stiffness, pre- and post-processing). Application of the FEM in different areas of engineering analysis is presented in theory and practice: static linear elasticity, dynamics (modal analysis and transient problem), thermal analysis. In the practical part students will learn how to create an appropriate computational model and realise the FE analysis using commercial software. |
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| Teaching methods and criteria: | ||||
| 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: | ||||
| The course-unit credits award is based on the individual preparation of two semester projects, proving students have mastered the work with a selected FE package. Examination has the form of a written test. |
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| Controlled participation in lessons: | ||||
| Attendance at practical training is obligatory. Study progress is checked in seminar work during the whole semester. | ||||
| Type of course unit: | ||||
| Lecture | 13 × 2 hrs. | optionally | ||
| Computer-assisted exercise | 13 × 2 hrs. | compulsory | ||
| Course curriculum: | ||||
| Lecture | 1. Discretisation in Continuum Mechanics by different numerical methods 2. Variational formulation of FEM, historical notes 3. Illustration of FE algorithm on the example of 1D elastic bar 4. Line elements in 2D and 3D space - bars, beams, frames 5. Plane and axisymmetrical elements, mesh topology and stiffness matrix structure 6. Isoparametric formulation of elements 7. Equation solvers, domain solutions 8. Convergence, compatibility, hierarchical and adaptive algorithms 9. Thin-walled elements in bending, hermitean shape functions 10.Plate and shell elements 11.FEM in dynamics, consistent and diagonal mass matrix 12.FEM in heat conduction problems, stationary and transient analysis 13.Explicit FE solution |
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| Computer-assisted exercise | 1. Illustration of algorithm of Finite Difference Method on selected elasticity problem 2. Application of Ritz Method on the same problem 3. Commercial FE packages - brief overview 4. ANSYS - Introduction to environment and basic commands 5. Frame structure in 2D 6. Frame structure in 3D 7. Plane problem of elasticity 8. 3D problem, pre- and postprocessing 9. Consultation of individual projects 10.Consultation of individual projects 11.Modal analysis by ANSYS 12.Transient problem of heat conduction and thermal stress analysis 13.Presentation of semester projects |
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| Literature - fundamental: | ||||
| 1. Zienkiewicz, O. C., Taylor, R. L., The Finite Element Method for Solid and Structural Mechanics, Elsevier, 2013 | ||||
| 2. R.D.Cook: Concepts and Applications of Finite Element Analysis, J.Wiley, 2001 | ||||
| 3. K.-J.Bathe: Finite Element Procedures, K.-J.Bathe, 2014 | ||||
| Literature - recommended: | ||||
| 1. Z.Bittnar, J.Šejnoha: Numerické metody mechaniky 1, 2, Vydavatelství CVUT, Praha, 1992 | ||||
| 2. J.Petruška: MKP v inženýrských výpočtech http://www.umt.fme.vutbr.cz/images/opory/MKP%20v%20inzenyrskych%20vypoctech/RIV.pdf | ||||
| 7. V.Kolář, I.Němec, V.Kanický: FEM principy a praxe metody konečných prvků, Computer Press, 2001 | ||||
| The study programmes with the given course: | |||||||||
| Programme | Study form | Branch | Spec. | Final classification | Course-unit credits | Obligation | Level | Year | Semester |
| B3A-P | full-time study | B-MET Mechatronics | -- | Cr,Ex | 5 | Compulsory | 1 | 3 | W |
| M2A-P | full-time study | M-IMB Engineering Mechanics and Biomechanics | -- | Cr,Ex | 5 | Compulsory | 2 | 1 | W |
| M2A-P | full-time study | M-MTI Materials Engineering | -- | Cr,Ex | 5 | Elective (voluntary) | 2 | 1 | W |
| M2I-P | full-time study | M-FLI Fluid Engineering | -- | Cr,Ex | 5 | Compulsory | 2 | 2 | W |
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