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Lecturer(s)
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Kantor Martin, Ing. Ph.D.
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Course content
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1. Historical overview of numerical simulation methods development 2. Introduction to finite element method, element types, feed approximation, base element matrix 3. Basic physical equations, stiffness matrix, boundary conditions, analysis of results, 4. Basic principles of numerical simulation in ANSYS FLUENT, networking, definition of boundary conditions, postprocessing 5. Modeling of basic elastostatic problems 6. Introduction to finite volume method 7. Basic physical equations in fluid mechanics and thermodynamics, boundary and initial conditions 8. Heat conduction, stationary and non-stationary 9. Modeling of basic problems in fluid mechanics 10. Modeling of convection heat transfer 11. Modeling of advanced 3D problems in fluid mechanics and thermodynamics
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Learning activities and teaching methods
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unspecified
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Learning outcomes
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Introduction to numerical methods for Euler and Navier-Stokes equations. Modified equation analysis Finite difference methods, finite volume and spectral element methods. Explicit vs. implicit time stepping methods. Solution of systems of linear algebraic systems. Higher-order vs. higher resolution methods. Computation of turbulent flows. Compressible flows.
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Prerequisites
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unspecified
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Assessment methods and criteria
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unspecified
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Recommended literature
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Amir, R., Khoei. Extended Finite Element Method: Theory and Applications. Wiley and Sons, 2015. ISBN 978-1-118-45768-9.
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Fürst, J., Kozel, K. Numerické řešení problémů proudění I. ČVUT v Praze, 2001.
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Grieb, P. Digital Prototyping. Hanser, 2010.
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online podklady. www.ansys.com, www.simscale.com.
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P. Sváček, M. Feistauer. Metoda konečných prvků. ČVUT Praha, 2006. ISBN ISBN 80-01-03522-.
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