Lecturer(s)
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Course content
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Contents of part 2: 1. Aerodynamics and hydrodynamics. Laminar and turbulent flow. 2. Surface undulation and its control in computer design. 3. Effect of fractures, grooves and cracks. 4. Non-stationary phenomena. Von Karman's Beliefs, Their Risks and Suppression. 5. Examples of computer methods of aerodynamic calculations. 6. Basics of proper design with regard to aerodynamic properties. 7. Thermodynamics. Basic concepts and units. Conduction, convection, radiation. 8. Possible sources of heat and their consideration in the design proposal. 9. Samples of calculation methods of thermodynamic calculations. 10. Working with a computer model - conduction 11. Working with a computer model - convection 12. Working with a computer model - radiation 13. Basics of the correct designer design with regard to thermodynamic properties.
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Learning activities and teaching methods
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- Participation in classes
- 26 hours per semester
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prerequisite |
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Knowledge |
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credit from subjects: Advanced 3D modeling techniques 1, 2 and 3 |
credit from subjects: Advanced 3D modeling techniques 1, 2 and 3 |
Credit from the subject: Technical aspects of industrial design 1 |
Credit from the subject: Technical aspects of industrial design 1 |
Skills |
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knowledge from subjects: Advanced 3D modeling techniques 1, 2 and 3 |
knowledge from subjects: Advanced 3D modeling techniques 1, 2 and 3 |
Knowledge of the subject: Technical aspects of industrial design 1 |
Knowledge of the subject: Technical aspects of industrial design 1 |
learning outcomes |
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Knowledge |
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the student becomes familiar with the basic concepts in the field of fluid flow |
the student becomes familiar with the basic concepts in the field of fluid flow |
the student gets to know the basics of computer simulation of fluid flow |
the student gets to know the basics of computer simulation of fluid flow |
the student gets to know the basic terms in the field of heat propagation |
the student gets to know the basic terms in the field of heat propagation |
the student gets to know the basics of computer simulation of heat propagation |
the student gets to know the basics of computer simulation of heat propagation |
the student becomes familiar with the preparation of a 3D model for simulation calculations |
the student becomes familiar with the preparation of a 3D model for simulation calculations |
Skills |
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the student can formulate the required task of analyzing the aerodynamic or hydraulic flow around the 3D model |
the student can formulate the required task of analyzing the aerodynamic or hydraulic flow around the 3D model |
the student can prepare a suitable model for fluid flow analysis |
the student can prepare a suitable model for fluid flow analysis |
the student can prepare a suitable model for the analysis of heat propagation |
the student can prepare a suitable model for the analysis of heat propagation |
the student can formulate the requirements for the role of heat propagation in a 3D model |
the student can formulate the requirements for the role of heat propagation in a 3D model |
the student manages to communicate professionally with specialists in the field of aerodynamics and thermodynamics |
the student manages to communicate professionally with specialists in the field of aerodynamics and thermodynamics |
teaching methods |
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Knowledge |
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Exercises on PC |
Exercises on PC |
Skills |
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Exercises on PC |
Exercises on PC |
assessment methods |
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Knowledge |
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Systematic observation of the student |
Systematic observation of the student |
Composite examination (Written part + oral part) |
Composite examination (Written part + oral part) |
Recommended literature
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Ing. Marek Pagáč, Ph.D. Učebnice SolidWorks.. 2017. ISBN 978-80-270-0918-3.
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Lombard M. SolidWorks 2013 Bible. Indianapolis USA, 2013. ISBN 978-1-118-50840-4.
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Lombard M. Surfacing and Complex Shape Modeling. Indianapolis USA, 2013. ISBN 978-0-470-25823-1.
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