Sylabus predmetu AFDI - Finite Elemet Method in Wood Technology (FFWT - SS 2018/2019)

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Course code:
Course title in Czech:
Finite Elemet Method in Wood Technology
Course title in English: Finite Elemet Method in Wood Technology
Semester: SS 2018/2019
Mode of completion and number of credits: Fulfillment of requirements (4 credits)
Mode of delivery and timetabled classes:
full-time, 0/3 (hours of lectures per week / hours of seminars per week)
part-time, 18/0 (lectures per period / seminars per period)
Level of course: bachelor; master; master continuing
Course type: required
Type of delivery:
Mode of delivery for our mobility students abroad: -- item not defined --
Language of instruction:
Course supervisor:
Course supervising department:
Ing. David Děcký, Ph.D. (instructor, lecturer)
Ing. Jaromír Milch, Ph.D. (instructor, lecturer)
Ing. Pavlína Suchomelová (instructor, lecturer)
Ing. Jan Tippner, Ph.D. (examiner, instructor, lecturer, supervisor, tutor)
Mgr. Ing. Miroslav Trcala, Ph.D. (instructor, lecturer)
Ing. Barbora Vojáčková, DiS. (instructor, lecturer)
Prerequisites: State Bachelor Examination
Timetable in this semester:
-- item not defined --
Aim of the course and learning outcomes:
To acquire knowledge of mechanics of continuum and thermodynamics of continuum in advanced problems of wood technology and processing, knowledge of principles of the finite element method, the knowledge of procedure of numerical model building. To acquire advanced skills of use of the simulation software include scripting.
Course content:
1.Introduction: mechanical models of solid wood (orthotropy, diversion fiber, the influence of moisture, interpretation of results). Selected numerical methods for solving of differential equations, introduction of variational methods, introduction to finite element method, modeling of basic physical phenomena, implementation of fields of physics. (allowance 0/3)
Mechanical models of composites (layered composites with fiber inclination, bonded line, particle composites, modeling of the density distribution, sandwiches, laminates). (allowance 0/3)
Diffusion and coupled models of wood and wood-based materials (heat, humidity, coupling -thermo and hygro-expansion). (allowance 0/3)
Orthotropic shell models with composite wood-based physical analysis of the, the beam models for static and dynamic solutions. (allowance 0/3)
5.Solid mechanics models of details of wooden structures, plane thermal problems (structure, thermal bridges). (allowance 0/3)
Solid thermal analysis (heating, drying, modification). (allowance 0/3)
Probabilistic sensitivity analysis (impact factors, changes in geometry, material changes). (allowance 0/3)
Dynamic analysis for beam, shell and solid elements (modal, harmonic and transient problems), acoustic analysis. (allowance 0/6)
9.Design optimization and topology optimization. (allowance 0/3)
Work on the project, presentation / defense projects. (allowance 0/9)
Learning activities and teaching methods:
Type of teaching method
Daily attendance
Combined form
39 h
18 h
consultation24 h
34 h
project work
7 h
12 h
public presentation (oral)
3 h
1 h
preparation for regular assessment3 h3 h
preparation of presentation
6 h
6 h
writing of seminar paper30 h
38 h
112 h
112 h
Assessment methods:
A defense of seminary project: presentation and discussion. The project (10-20 pages, standard structure) consist of building of numerical model, numerical analysis and interpretation of results.
Assessment criteria ratio:
Requirement type
Daily attendanceCombined form
Total0 %0 %
Recomended reading and other learning resources:
MADENCI, E. -- GUVEN, I. The finite element method and applications in engineering using ANSYS. New York: Springer, 2006. 686 p. ISBN 0-387-28289-0.
KOLÁŘ, V. -- NĚMEC, I. -- KANICKÝ, V. FEM - Principy a praxe metody konečných prvků. 1st ed. Praha: Computer Press, 1997. 12 p. ISBN 80-7226-021-9.
NAKASONE, Y. -- YOSHIMOTO, S. -- STOLARSKI, T A. Engineering analysis with ANSYS software. Amsterdam: Butterworth-Heinemann, 2006. 456 p. ISBN 0-7506-6875-X.
MOAVENI, S. Engineering fundamentals: an inroduction to engineering. 4th ed. Stamford, CT: Cengage Learning, 2011. 700 p. ISBN 978-1-4390-6210-4.
Finite element analysis: theory and application with ANSYS. 3rd ed. Upper Saddle River, N.J.: Pearson Prentice Hall, 861 p. ISBN 978-0-13-241651-1.
Finite element simulations with ANSYS workbench 14: [theory, applications, case studies]. Mission, Kan.: Schroff Development Corp., 2012. 602 p. ISBN 978-1-58503-725-4.
TOPPING, B H V. Advances in computational structural mechanics. Edinburgh: Civil-comp press, 1998. 472 p. ISBN 0-948749-57-1.
BARBERO, E J. Finite element analysis of composite materials. Boca Raton: CRC Press, 331 p. ISBN 978-1-4200-5433-0.
Multiphysics modelling with finite element methods. New Jersey ;: London :, 422 p. ISBN 9789812568434.

BRDIČKA, M. -- SAMEK, L. -- SOPKO, B. Mechanika kontinua. 3rd ed. Praha: Academia, 2005. 799 p. Česká matice technická ;. ISBN 80-200-1344-X.
GRIFFITHS, D. Programming the finite element method. 5th ed. Chichester: Wiley, 2014. 664 p. ISBN 978-1-119-97334-8.
TOPPING, B H V. -- KUMAR, B. Developments in analysis and design using finite element methods. Edinburgh: Civil-Comp, 1999. 282 p. ISBN 0-948749-61-X.
ZIENKIEWICZ, O. -- TAYLOR, R. The finite element method : Solid and fluid Mechanics, dynamics and non-linearity . Volume 2. 4th ed. Berkshire: McGraw-Hill, 1991. 807 p. ISBN 0-07-084175-6.
Process modelling and simulation with finite element methods. Singapore: World Scientific, 2004. 382 p. ISBN 981-238-793-5.

Course listed in study plans for this semester:
Field of study C-WE-WE Wood engineering, full-time form, initial period WS 2018/2019
Field of study C-WE-WE Wood engineering, part-time form, initial period WS 2018/2019
Course listed in previous semesters:
Teaching place:

Last modification made by Ing. Alice Malá on 01/03/2019.

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