|Course Name||Code||Semester||T+U Hours||Credit||ECTS|
|Thermochemical Tech. Of Metallurgical Processes||IMM 566||0||3 + 0||3||6|
|Recommended Optional Courses|
|Course Coordinator||Prof.Dr. ŞADUMAN ŞEN|
|Course Objective||To learn thermo-chemical processes where are used in production of industrial minerals and materials treatment|
|Course Content||Basic termo chemical processes in extractive metallurgy|
|#||Course Learning Outcomes||Teaching Methods||Assessment Methods|
|Week||Course Topics||Preliminary Preparation|
|1||Industrial minerals, preparation and processing|
|2||Extractive metallurgical processes|
|3||Stoichiometric, equilibrium and reactions|
|4||Formation energies of metal and compounds|
|5||Heat capacity, heat of reaction|
|6||Diffusion theory and mechanism|
|8||Reduction of metal oxides|
|12||Chemical vapor deposition|
|13||Physical vapor deposition|
|14||Photo chemical reaction|
|Course Resources||. Experimental Approach to Electrochemistry, Selley N.J., John Wiley and Sons, Inc., 1977, New York.
.Electrochemistry, Rieger P.H., Prentice-Hall, 1982, New Jersey, U.S.A.
.Chemical Metallurgy, Moore J.J., Butterworths and Co., 1981, London.
.Industrial Electrochemistry, Pletcher D., Chapman and Hall, 1982, New York.
.Principles of Extractive Metallurgy, Rosenqvist, T., McGraw-Hill, Inc., 1974, New York.
.Electrochemical Methods, Bard A.J. and Faulkner L.R., John Wiley and Sons, Inc., 1980, New York.
|Order||Program Outcomes||Level of Contribution|
|1||Ability to access wide and deep information with scientific researches in the field of Manufacturing Engineering, evaluate, interpret and implement the knowledge gained in his/her field of study|
|2||Ability to consolidate Manufacturing Engineering problems, develop proper method(s) to solve and apply the innovative solutions to them|
|3||Gain comprehensive information on modern techniques, methods and their borders which are being applied to Manufacturing Engineering|
|4||Ability to design and apply analytical, modelling and experimental based research, analyze and interpret the faced complex issues during the design and apply process|
|5||Analytical modeling and experimental design based on research and application capabilities; the ability to analyze and interpret complex situations in this process|
|6||Awareness of the new and developing practices of the profession; the ability to examine and learn when necessary|
|7||Design and apply theoretical, experimental and model-based research; analyze and solve complicated problems in this process|
|8||Develop new and / or original ideas and methods; design complex systems or processes and develop innovative / alternative solutions in their designs.|
|9||The ability to transcribe the processes and outcomes of their work in a systematic and explicit way, either in writing or verbally, in the national and international contexts,|
|10||It considers social, scientific and ethical values in the collection, interpretation, announcement of data and in all professional activities.|
|11||To be able to develop strategy, policy and implementation plans on issues related to manufacturing engineering and to be able to evaluate the results obtained within the framework of quality processes|
|12||Students are aware of the social, environmental, health, safety, legal aspects of project management and business practices and limitations on their engineering applications.|
|Semester Studies||Contribution Rate|
|1. Ara Sınav||40|
|1. Performans Görevi (Seminer)||30|
|1. Yıl İçinin Başarıya||60|
|ECTS - Workload Activity||Quantity||Time (Hours)||Total Workload (Hours)|
|Course Duration (Including the exam week: 16x Total course hours)||16||3||48|
|Hours for off-the-classroom study (Pre-study, practice)||16||3||48|
|Performance Task (Seminar)||1||10||10|
|Total Workload / 25 (Hours)||6.04|