GAZI UNIVERSITY INFORMATION PACKAGE - 2018 ACADEMIC YEAR

COURSE DESCRIPTION
HEAT TRANSFER/MM 309 E
Course Title: HEAT TRANSFER
Credits 4 ECTS 5
Semester 5 Compulsory/Elective Compulsory
COURSE INFO
 -- LANGUAGE OF INSTRUCTION
  English
 -- NAME OF LECTURER(S)
  Prof. Şenol BAŞKAYA, Prof. Dr. İlhami HORUZ, Prof. Dr. Atilla BIYIKOĞLU, Assoc. Prof. Dr. Oğuz TURGUT
 -- WEB SITE(S) OF LECTURER(S)
  websitem.gazi.edu.tr/site/baskaya, websitem.gazi.edu.tr/site/ilhamihoruz, w3.gazi.edu.tr/~abiyik/, websitem.gazi.edu.tr/site/oturgut
 -- EMAIL(S) OF LECTURER(S)
  baskaya@gazi.edu.tr, ilhamihoruz@gazi.edu.tr, abiyik@gazi.edu.tr, oturgut@gazi.edu.tr
 -- LEARNING OUTCOMES OF THE COURSE UNIT
Learning the mechanism of heat transfer and thermal characteristics of the environment.
Learning the basic concepts of heat transfer by conduction and making calculations
Understanding the convective heat transfer calculations and applications
Learning the basic concepts of heat transfer by radiation and making calculations
Analyzing the heat transfer problems, resolving and gaining the ability to interpret the results




 -- MODE OF DELIVERY
  The mode of delivery of this course is face to face
 -- PREREQUISITES AND CO-REQUISITES
  MM203E Thermodynamics I
 -- RECOMMENDED OPTIONAL PROGRAMME COMPONENTS
  There is no recommended optional programme component for this course.
 --COURSE CONTENT
1. Week  Basic of Heat Transfer: Heat transfer mechanisms, conduction, thermal conductivity, convection and radiation, simultaneous heat transfer mechanisms.
2. Week  Heat Conduction: General heat conduction equation, boundary and initial conditions, setady one dimensional heat conduction, heat generation in a solid
3. Week  Steady Heat Conduction: Steady heat conduction in plane walls, thermal contact resistance, generalized thermal resistance networks, heat conduction in
4. Week  Steady Heat Conduction: Critical radius of insulation, heat transfer from finned surfaces, fin equation, fin efficiency, fin effectiveness.
5. Week  Transient Heat Conduction. Lumped system analysis, Transient Heat Conduction: Lumped system analysis, transient conduction in large plane walls, long
6. Week  Numerical Methods in Steady Conduction: Finite difference formulation of one-dimensional and two-dimensional steady heat conduction, boundary nodes, i
7. Week  Numerical Methods in Transient Conduction: One and two dimensional transient heat conduction, controlling numerical error.
8. Week  Midterm I
9. Week  Forced Convection: Fundamentals of convection, classification of fluid flows, velocity boundary layer, thermal boundary layer, laminar and turbulent f
10. Week  External Forced Convection: Drag force and heat transfer in external flow, parallel flow over flat plates, flow across cylinders and spheres, flow acr
11. Week  Internal Forced Convection: Mean velocity, mean temperature, the entry region, constant surface heat flux and temperature boundary conditions, laminar
12. Week  Natural Convection: Physical mechanism, natural convection over surfaces and inside enclosures, combined natural and forced convection.
13. Week  Thermal Radiation: Blacbody radiation, radiation intensity, radiative properties, Kirchhoff's law, atmospheric and solar radiation, view factor and v
14. Week  Midterm II
15. Week  Radiation Heat Transfer: Radiation heat transfer between black surfaces, between diffuse gray surfaces, radiation shields, radiation exchange with emi
16. Week  FINAL
 -- RECOMMENDED OR REQUIRED READING
  Y. A. Çengel, A. J. Ghajar. Heat and Mass Transfer: Fundamentals and Applications. Mc. Graw Hill.
 -- PLANNED LEARNING ACTIVITIES AND TEACHING METHODS
  Lecture, question-answer, demontration, drill, practice.
 -- WORK PLACEMENT(S)
  No
 -- ASSESSMENT METHODS AND CRITERIA
 
Quantity
Percentage
 Mid-terms
2
60
 Assignment
0
0
 Exercises
0
0
 Projects
0
0
 Practice
0
0
 Quiz
0
0
 Contribution of In-term Studies to Overall Grade  
60
 Contribution of Final Examination to Overall Grade  
40
 -- WORKLOAD
 Efficiency  Total Week Count  Weekly Duration (in hour)  Total Workload in Semester
 Theoretical Study Hours of Course Per Week
15
4
60
 Practising Hours of Course Per Week
13
1
13
 Reading
15
2
30
 Searching in Internet and Library
0
 Designing and Applying Materials
0
 Preparing Reports
0
 Preparing Presentation
0
 Presentation
0
 Mid-Term and Studying for Mid-Term
2
10
20
 Final and Studying for Final
1
10
10
 Other
0
 TOTAL WORKLOAD: 
133
 TOTAL WORKLOAD / 25: 
5.32
 ECTS: 
5
 -- COURSE'S CONTRIBUTION TO PROGRAM
NO
PROGRAM LEARNING OUTCOMES
1
2
3
4
5
1Engineering graduates with sufficient theoretical and practical background for a successful profession and with application skills of fundamental scientific knowledge in the engineering practice.X
2Engineering graduates with skills and professional background in describing, formulating, modeling and analyzing the engineering problem, with a consideration for appropriate analytical solutions in all necessary situationsX
3Engineering graduates with the necessary technical, academic and practical knowledge and application confidence in the design and assessment of machines or mechanical systems or industrial processes with considerations of productivity, feasibility and environmental and social aspects.X
4Engineering graduates with the practice of selecting and using appropriate technical and engineering tools in engineering problems, and ability of effective usage of information science technologiesX
5Ability of designing and conducting experiments, conduction data acquisition and analysis and making conclusionsX
6Ability of identifying the potential resources for information or knowledge regarding a given engineering issueX
7The abilities and performance to participate multi-disciplinary groups together with the effective oral and official communication skills and personal confidenceX
8Ability for effective oral and official communication skills in Turkish Language and, at minimum, one foreign languageX
9Engineering graduates with motivation to life-long learning and having known significance of continuous education beyond undergraduate studies for science and technologyX
10Engineering graduates with well-structured responsibilities in profession and ethicsX
11Engineering graduates who are aware of the importance of safety and healthiness in the project management, workshop environment as well as related legal issues
12Consciousness for the results and effects of engineering solutions on the society and universe, awareness for the developmental considerations with contemporary problems of humanityX