Summary of Study |
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Explanatory Notes
Instructions
Anotation:
The definition of fundamental equations of heat and mass transfer in electromagnetic field in continuum. Thermal effects of electromagnetic field. The definition of the problems of induction, dielectric and arc heating. Similarity and analogy of equations and their use. Numerical methods in electroheat.
Content:
This course deals with physical laws of thermodynamics, heat transfer, mass and energy transfer relevant for electrical heating devices design. Special emphasis is put on theoretical and practical heat transfer (conduction, convection, radiation). Results of theoretical treatment are shown using practical examples from nowdays design of electroheat devices.
Course outlines:
1. | | Physical foundations of electrical heat |
2. | | Mathematical apparatus of the continuum |
3. | | Physical foundations - momentum transfer, continuity equations |
4. | | Fourier-Kirchhoff heat transfer equation |
5. | | Heat transfer - Convection, Criteria definitions |
6. | | Radiative Heat transfer - Planck's law, Kirchhoff's law |
7. | | Radiative Heat transfer - solutions using configuration factors |
8. | | The problem of direct resistive heating |
9. | | The problem of indirect resistive heating |
10. | | The problem of induction heating of non-ferromagnetic materials |
11. | | The problem of ferromagnetic material heating, |
12. | | The problem of dielectric and microwave heating |
13. | | Mathematical models of an electric arc |
14. | | Reserve |
Exercises outline:
1. | | Physical foundations of electrical heat |
2. | | Mathematical apparatus of the continuum |
3. | | Physical foundations - momentum transfer, continuity equations |
4. | | Fourier-Kirchhoff heat transfer equation |
5. | | Heat transfer - Convection, Criteria definitions |
6. | | Radiative Heat transfer - Planck's law, Kirchhoff's law |
7. | | Radiative Heat transfer - solutions using configuration factors |
8. | | The problem of direct resistive heating |
9. | | The problem of indirect resistive heating |
10. | | The problem of induction heating of non-ferromagnetic materials |
11. | | The problem of ferromagnetic material heating, |
12. | | The problem of dielectric and microwave heating |
13. | | Mathematical models of an electric arc |
14. | | Reserve |
Literature:
John H. Lienhard IV, John H. Lienhard V: A Heat Transfer Textbook, 4th edition. Massachusetts Institute of
Technology. online:
http://web.mit.edu/lienhard/www/ahtt.html,
Holman, J.P.: Heat Transfer, McGraw-Hill, 2001 Metaxas, A.C: Foundations of Electroheat :
A Unified Approach, - John Wiley & Sons; 1 edition (July 11, 1996) Trott, M.: The Mathematica GuideBook
for Numerics, Springer; 1 edition (October 12, 2005)
Thermal Radiation Heat Transfer, 5th Edition by John R. Howell (Author), M. Pinar Menguc (Author), Robert
Siegel (Author) ISBN-10: 1439805334Holman, J.P.: Heat Transfer, McGraw-Hill, 2001
Metaxas, A.C: Foundations of Electroheat : A Unified Approach, John Wiley & Sons; 1 edition (July 11, 1996)
Trott, M.: The Mathematica GuideBook for Numerics, Springer; 1 edition (October 12, 2005)
Requirements:
Subject is included into these academic programs:
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Proposal and Realization: I. Halaška (K336), J. Novák (K336) |