Nov 12, 2019   7:14 p.m. Svätopluk
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Course syllabus MSTP06_6I - Modelling and Simulation of Technological processes (MTF - WS 2019/2020)


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University: Slovak University of Technology in Bratislava
Faculty: Faculty of Materials Science and Technology in Trnava
Course unit code: MSTP06_6I
Course unit title: Modelling and Simulation of Technological processes
Mode of delivery, planned learning activities and teaching methods:
lecture2 hours weekly / 26 hours per semester of study (on-site method)
26 hours per semester of study (combined method)
laboratory/construction practice1 hour weekly / 13 hours per semester of study (on-site method)
13 hours per semester of study (combined method)
project/semestral paper1 hour weekly / 13 hours per semester of study (on-site method)
13 hours per semester of study (combined method)

 
Credits allocated: 5
 
Recommended semester/trimester: Welding and Joining of Materials - master (compulsory), 3. semester
Welding and Joining of Materials - master (compulsory), 3. semester
Materials Engineering - master (semi-compulsory), 1. semester
Materials Engineering - master (semi-compulsory), 1. semester
Process Automation and Informatization in Industry - master (semi-compulsory), 1. semester
Process Automation and Informatization in Industry - master (semi-compulsory), 1. semester
Production Devices and Systems - master (semi-compulsory), 3. semester
Production Devices and Systems - master (semi-compulsory), 3. semester
Level of study: 2.
Prerequisites for registration: none
 
Assesment methods:
Active participation in exercises and succesful passing two control tasks during the semester (20 %).
 
Learning outcomes of the course unit:
Subject "Modeling and simulation of technological processes" allows students to enter into the problem of development and solution of simulation models. The basis of computer simulation is the finite element method. Students will obtain basic theoretical knowledge and practical skills in modeling and numerical simulation of chosen technological processes. Emphasis is placed on understanding of the basic philosophy of design, verification and application of simulation models for solving engineering problems as a means for progressive design, analysis and optimization of technological processes. Students will also acquire an overview of the commercial specialized software systems for simulation of technological processes.
 
Course contents:
Theoretical basis for modeling, models of processes and systems, distribution patterns according to process parameters, the selection of a method and model solutions. Theoretical basis for modeling of temperature, stress-strain and electro-magnetic fields. Characteristics of the basic material models - elastic, elasto-plastic, visco-plastic, hyperelastic. Material Databases. The finite element method. Overview of commercial software systems for simulation of technological processes. Development of simulation model. Development of geometric models. Generation of finite element mesh. Definition of linear and nonlinear material properties, modeling of phase transformations, input of initial and boundary conditions. Specification of computation methods. The accuracy and stability of the solution. Processing and evaluation of the results of numerical solutions. Numerical simulation of selected technological processes depending on the major specification- Numerical simulation of heating pocesses and processes including the energetical influence of surfaces, heat treatment processes, forming, welding, casting using the ANSYS software or other available software systems.
 
Recommended or required reading:
Basic:
KUNEŠ, J. -- FRANTA, V. Základy modelování. Praha : SNTL, 1989. 263 p.
KUNEŠ, J. Modelování tepelných procesú. Praha : SNTL, 1989. 423 p. ISBN 80-03-00134-X.
ŽMINDÁK, M. -- GRAJCIAR, I. -- NOZDROVNICKÝ, J. Modelovanie a výpočty v metóde konečných prvkov: Diel I - modelovanie v ANSYSe. Žilina : Vedeckotechnická spoločnosť pri Žilinskej univerzite, 2004. 208 p. ISBN 80-968823-5-X.
BENČA, Š. Výpočtové postupy MKP pri riešení lineárnych úloh mechaniky. Bratislava : STU v Bratislave, 2006. 150 p. ISBN 80-227-2404-1.
BENČA, Š. Riešenie nelineárnych pevnostných úloh pomocou MKP. Bratislava : STU, 2009. 205 p. ISBN 978-80-227-3077-8.
TARABA, B. -- BEHÚLOVÁ, M. -- KRAVÁRIKOVÁ, H. Mechanika tekutín. Termomechanika: Zbierka príkladov. Trnava : AlumniPress, 2007. 242 p. ISBN 978-80-8096-021-6.
VANEK, O. -- MINÁRSKY, E. -- KEMPNÝ, M. Technologické procesy a ich modelovanie: Príručka na cvičenia. Bratislava : STU v Bratislave, 1995. 161 p. ISBN 80-227-0763-5.
KUTIŠ, V. -- MURÍN, J. -- PAULECH, J. -- GOGA, V. Metóda konečných prvkov v mechatronike 1: Úvod do programu ANSYS. Bratislava : STU, 2014. 159 p. ISBN 978-80-227-4129-3.
MINÁROVÁ, M. Príklady inžinierskej praxe s implementáciou v programe ANSYS. Bratislava : Nakladateľstvo STU, 2013. 118 p. ISBN 978-80-227-4047-0.
NAKASONE, Y. -- YOSHIMOTO, S. -- STOLARSKI, T. Engineering Analysis with ANSYS Software. Amsterdam : Elsevier, 2008. 456 p. ISBN 978-0-7506-6875-0.
MADENCI, E. -- GUVEN, I. The Finite Element Method and Applications in Engineering Using ANSYS. University of Arizona: Springer, 2006., 2006. 689 p. ISBN 0-387-28289-0.

 
Language of instruction: slovak and english or english
 
Notes:
 
Courses evaluation:
Assessed students in total: 577

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2,4 %9,2 %21,3 %32,6 %33,3 %1,2 %
Name of lecturer(s): Ing. Eva Babalová, PhD. (examiner, instructor) - slovak, english
doc. RNDr. Mária Behúlová, CSc. (examiner, instructor, lecturer, person responsible for course) - slovak, english
Ing. Štefan Hajdu, PhD. (instructor) - slovak
Ing. Helena Kraváriková, PhD. (examiner, instructor) - slovak
Ing. Máté Nagy (instructor)
 
Last modification: 20. 12. 2018
Supervisor: doc. RNDr. Mária Behúlová, CSc. and programme supervisor


Last modification made by Bc. Jana Rohaľová on 12/20/2018.

Type of output: