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The aim of the first part of the course is to make students acquainted with most frequent applications of optical radiation, modern photometric and colorimetric devices used in practice, fundamentals of light control and design of dynamic lighting including new trends in light sources and luminaire progress. The aim of the second part of the course is to become students acquainted with heat transfer laws, heat pumps and problems of global optimization on electrical power engineering. |
The aim is to gain knowledge of heat transfer, physical similarity theory, mathematical models frequently used components of energy systems (heat exchangers, heat pumps, thermal storage tanks, air treatment equipment). Are discussed mathematical models of induction and arc of electro-thermal equipment. |
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1. Heat transfer: Fourier law, heat equation |
2. Physical similarity theory, Fourier and Nusselt number |
3. Convective heat transfer coefficient at free, forces and transient convection |
4. Heat exchangers: equations, types, use |
5. Heat pumps: equations, types, use |
6. Mathematical models of thermal storage tanks, solar collectors, fluid mixing |
7. Humid air thermodynamic principles, Mollier enthalpy diagram |
8. Induction heating of materials: circuit access |
9. Induction heating of materials: alemag. field access |
10. FEM for thermal and elmag. Field, boundary and initial conditions |
11. Arc furnaces: types, construction, connection to the grid |
12. Arc models and its influence on the grid, higher harmonic frequencies and flicker compensation |
13. Supplementary systems for induction heating devices (sources, cooling systems) |
14. Reserve |
1. Heat transfer: Fourier law, heat equation\\ |
2. Physical similarity theory, Fourier and Nusselt number\\ |
3. Convective heat transfer coefficient at free, forces and transient convection\\ |
4. Heat exchangers: equations, types, use\\ |
5. Heat pumps: equations, types, use\\ |
6. Mathematical models of thermal storage tanks, solar collectors, fluid mixing\\ |
7. Humid air thermodynamic principles, Mollier enthalpy diagram\\ |
8. Induction heating of materials: circuit access\\ |
9. Induction heating of materials: alemag. field access\\ |
10. FEM for thermal and elmag. Field, boundary and initial conditions\\ |
11. Arc furnaces: types, construction, connection to the grid\\ |
12. Arc models and its influence on the grid, higher harmonic frequencies and flicker compensation\\ |
13. Supplementary systems for induction heating devices (sources, cooling systems)\\ |
14. Reserve\\ |
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[[3] [SynthLight Handbook|http://www.new-learn.info/packages/synthlight/handbook/doc/chapter1.pdf]\\ |
PREF. BY JEAN LUCAS. Induction, conduction électrique dans l'industrie. Paris: Centre Français de l'Électricité [u.a.], 1996. ISBN 2869950225. John H. Leinhard IV, John H. Leinhard V: A Heat Transfer Textbook, http://web.mit.edu/lienhard/www/ahtt.html\\ |
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[Secret life of electric light - https://www.youtube.com/watch?v=v0ES9TKAf_4\\ |
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