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Course
Code: : 5103101 Course
Name
: Advanced Heat
Transfer Instructor
: Asst. Assoc. Dr. Refet KARADAĞ Theoretical / Practical / Credit : 3 / 0 / 3
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HARRAN UNİVERSITY ENGINEERING FACULTY
MECHANICAL ENGI0NEERING DEPARTMENT
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Course Name |
Code |
Semester |
T+U |
Credit |
AKTS |
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Advanced Heat Transfer |
5103101 |
Fall |
3+0 |
3 |
5 |
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Prerequisite Courses |
None |
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Language of Course |
Turkish |
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Course class |
Compulsory |
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Coordinator of Course |
Asst. Assoc. Dr. Refet KARADAĞ |
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Instructor |
Asst. Assoc. Dr. Refet KARADAĞ |
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Course Assistant |
- |
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Objective of course |
Conduction,
convection and radiation heat transfer is to teach the basic principles and
enforce different application areas of engineering to teach numerical methods
used to solve the equations of heat transfer and enforce these equations to
engineering problems. |
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Course Learning Output |
Conduction,
convection and radiation to learn the principles, composite numerical methods
used in solving heat transfer problems and to investigate the results of
solution. |
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Course Contents |
The
concept of the continuum. Cartesian, cylindrical and spherical coordinates, the heat conduction. Time dependent heat
conduction. Transport characteristics of the equations. Solution methods. In
closed environments, the natural convection. Hydrodynamic and thermal
boundary layer. Flow, heat transfer channels. Composite heat transfer.
Improvement of heat transfer, the extended heat transfer surfaces. Thermal
insulation methods, thermal insulation standards. numerical
methods for solving heat transfer problems, finite difference, finite volume
and finite element method. |
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Weeks |
Plan
of Course at Semester |
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1 |
Removal and application of the General Heat Conduction Equation |
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2 |
Continuous One-Dimensional Heat Transfer Conditions, Orthogonal Functions, Fourier Expansions and Finite Fourier Transforms |
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3 |
Continuous two-and three-dimensional Heat Transfer Conditions: Separation of Variables Method Solutions |
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4 |
Natural convection in, planar and cylindrical surfaces, natural convection |
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5 |
Physical mechanism of heat radiation, radiation shape factor, gray, and the heat radiation from the real surfaces |
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6 |
Conduction, convection and radiation with the investigation and establishment of energy balance |
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7 |
Unsteady heat transfer, heat transfer in different time-Connected Solution Methods |
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8 |
Heat transfer, numerical methods: finite differences, finite volume and finite element method. |
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9 |
Derivation of Momentum and Energy Equations. |
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10 |
MID-TERM EXAM |
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11 |
Heat exchangers and their applications, heat exchanger types, the average heat transfer coefficient. |
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12 |
logarithmic mean temperature difference, effectiveness (ε)-NTU method |
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13 |
Compact heat exchangers, variable for the analysis of properties, heat exchanger design |
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14 |
FINAL EXAM |
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General Sufficiency |
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Required for the solution
of problems of heat
transfer methods can be used
and explore the results of solution |
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References |
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1. Heat transfer, seventh edition, Holman, J.P. London, 1992 2. Isı ve Kütle Geçişinin Temellleri, Frank P. Incropera, David P. Dewitt, 2001, Literatür yayınları. (Dördüncü basımdan çeviri. Çev: Taner Derbentli, Osman Genceli, Ali Güngör ve Diğerleri). 3. Örneklerle Isı Geçişi, Halıcı, F. ve Gündüz, M. Sakarya, 2001. |
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Form of Assessment |
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Mid Exam and Task/Project Average of
Arithmetical: %40 Final:%60 Projects:- Homework:- |