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Lecturer(s)
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Dostál Jiří, prof. PhDr. PaedDr. Ph.D.
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Havelka Martin, Mgr. Ph.D.
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Děrda Radim, Mgr.
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Course content
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Topics covered: -technical mechanics: basic terminology, classification of knowledge; -statics: force, torgue theorem, application: calculation of gravity centre of selected objects, truss structures; -dynamics: basic terminology and principles; - flexibility and rigidity: basic terminology and principles, deformation, tension, pressure, shear, bend, torsion, buckling, fixed-end beams and supported beams, special types of load: buckling (truss structure bonding), composite load (homogenous and heterogenous load), contoured strength, cyclic load; hydromechanics: flow in ideal and real liquid, calculation for the respective liquid, including piping and fixtures; - thermomechanics: basic terminology; thermostatics: longitudinal and dimensional dilatation of machine components, tenstion resulting from heat dilatation; smelting of metals; measuring of specific heat capacity; thermodynamics: basic terminology, thermodynamic system (TS), classification, reversible changes in TS, applications; analysis - Carnot circular cycle, heat efficiency, work diagram, heat diagram, indicator diagram, specific TS - Carnot cycle; thermokinetics: basic terminology, classification; conduction: field of temperature, Fourier's law, electric heat analogies; - convection> passage and transmission of heat through simple and composite wall, heat resistance, application in construction; - radiation: reflextion, absorption, - transmission: specific applications using specific materials.
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Learning activities and teaching methods
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Lecture, Work with Text (with Book, Textbook), Grafic and Art Activities
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Learning outcomes
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The aim of the course is to present selected structures from the field of mechanical engineering, technological normalization and mechanics to create a basis for creative application of the theory. Familiarity with construction of simple machinery components.
The student is able to practically implement selected knowledge from the field of technical mechanics both in practical life as well as general technical or specialized technical subject
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Prerequisites
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Finished classes of Theoretical basis of technical subjects
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Assessment methods and criteria
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Mark
Based on individual tasks to prove the basic awareness and practical skills related to the subject, in particular when designing technical objects. HAVELKA, M. Základy konstruování (Basics of structural design) (study support). Olomouc : UP (in print)
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Recommended literature
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Hloušek, J. (1992). Termomechanika. Brno : VUT. 297 s.
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Hofírek, M. (1998). Mechanika - dynamika (učebnice). Havlíčkův Brod : Fragment. 76 s.
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Hofírek, M. (1998). Mechanika - statika (pracovní sešit). Havlíčkův Brod : Fragment. 104 s.
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Hofírek, M. (1998). Mechanika - statika (učebnice). Havlíčkův Brod : Fragment. 96 s.
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Hofírek, M. (1998). Mechanika tekutin, hydromechanika a základy aerodynamiky (učebnice). Praha : Fragment.
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Hofírek, M. (1998). Termomechanika I.(učebnice). Havlíčkův Brod : Fragment. 100 s.
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Leinveber, J., Řasa, J. a Vávra, P. (2000). Strojnické tabulky. 3.dopl. vyd.. Praha : Scientia. 985 s.
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Mičkal, K. (1998). Sbírka úloh z technické maechaniky. Praha : Informatorium, 265 s.
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Mičkal, K. (1997). Technická mechanika I.. Praha : Informatorium. 213 s.
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Mičkal, K. (1998). Technická mechanika 2. Praha : Informatorium, 118 s.
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Nožička, J. aj. (1999). Termomechanika : Sbírka příkladů. Praha : ČVUT. 140 s.
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Rýc, Z. (1987). Technická mechanika 1. Statika, kinematika a dynamika, pružnost a pevnost.. Ostrava : VŠB.
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Rýc, Z. (1986). Technická mechanika 2. Mechanika tekutin, termomechanika. Ostrava : VŠB.
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