GAZI UNIVERSITY INFORMATION PACKAGE - 2019 ACADEMIC YEAR

COURSE DESCRIPTION
POWDER METALLURGY PRODUCTION PROCESSES/5091310
Course Title: POWDER METALLURGY PRODUCTION PROCESSES
Credits 3 ECTS 7.5
Semester 1 Compulsory/Elective Elective
COURSE INFO
 -- LANGUAGE OF INSTRUCTION
  Turkish
 -- NAME OF LECTURER(S)
  Prof.Dr. İbrahim USLAN, Assoc.Prof..Dr. Yusuf USTA
 -- WEB SITE(S) OF LECTURER(S)
  http://websitem.gazi.edu.tr/iuslan, http://websitem.gazi.edu.tr/uyusuf
 -- EMAIL(S) OF LECTURER(S)
  iuslan@gazi.edu.tr, yusta@gazi.edu.tr
 -- LEARNING OUTCOMES OF THE COURSE UNIT
To know powder metallurgy techniques and their applications.
To define, formulate and solve engineering problems.
To design, perform and evaluate experiments.
To apply the knowledge of mathematics, science and engineering.





 -- MODE OF DELIVERY
  The mode of delivery of this course is face to face.
 -- PREREQUISITES AND CO-REQUISITES
  There is no prerequisite or co-requisite for this course.
 -- RECOMMENDED OPTIONAL PROGRAMME COMPONENTS
  There is no recommended optional programme component for this course.
 --COURSE CONTENT
1. Week  Introduction to Powder Metallurgy Production Process
2. Week  Metal Powder Production Techniques: Milling and Electrolytic Process
3. Week  Metal Powder Production Techniques: Chemical,Gas and Water Atomization Process
4. Week  Metal Powder Productions Techniques: Spinning Disc and Rotational Electrode Atomization
5. Week  Characterization of Material Powders: Particle Size, Shape, Surface Area, Flow Rate
6. Week  Characterization of Material Powders: Particle Size, Shape, Surface Area, Flow Rate
7. Week  Characterization of Material Powders: Grain Density, Green Strength, Compressibility
8. Week  Powder Compaction: Pressing, Hot and Cold Isostatic Pressing
9. Week  Powder Compaction: Rolling, Extrusion, Powder injection molding.
10. Week  Sintering: Diffusion, Sintering Stages, Furnaces and Gasses
11. Week  Full Density Processes: Liquid Phase Sintering, Infiltration, Mechanical Consolidation
12. Week  Plasticity Theory of Porous Materials
13. Week  Mechanical Properties of Powder Metallurgy Parts
14. Week  Powder Systems and Applications
15. Week  Powder Systems and Applications
16. Week  Final exam
 -- RECOMMENDED OR REQUIRED READING
  1. Randall M. German, (1984), Powder Metallurgy Science, Metal Powder Industries Federation (MPIF), 2nd edition, New Jersey (NJ), USA. 2. Leander F. Pease III and William G. West, (2002), Fundamentals of Powder Metallurgy, MPIF, New Jersey (NJ), USA. 3. Werner Schatt, Klaus-Peter Wieters, (1997) Powder Metallurgy: Processing and Materials European Powder Metallurgy Association, EPMA, UK.
 -- PLANNED LEARNING ACTIVITIES AND TEACHING METHODS
  Lecture, Question & Answer, Demonstration, Drill - Practise
 -- WORK PLACEMENT(S)
  None.
 -- 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
14
3
42
 Practising Hours of Course Per Week
0
 Reading
14
1
14
 Searching in Internet and Library
14
2
28
 Designing and Applying Materials
5
2
10
 Preparing Reports
1
10
10
 Preparing Presentation
1
2
2
 Presentation
1
1
1
 Mid-Term and Studying for Mid-Term
2
15
30
 Final and Studying for Final
1
15
15
 Other
14
2
28
 TOTAL WORKLOAD: 
180
 TOTAL WORKLOAD / 25: 
7.2
 ECTS: 
7.5
 -- COURSE'S CONTRIBUTION TO PROGRAM
NO
PROGRAM LEARNING OUTCOMES
1
2
3
4
5
1Ability to access wide and deep information with scientific researches in the field of Engineering, evaluate, interpret and implement the knowledge gained in his/her field of studyX
2Ability to complete and implement “limited or incomplete data” by using the scientific methods.X
3Ability to consolidate engineering problems, develop proper method(s) to solve and apply the innovative solutions to themX
4Ability to develop new and original ideas and method(s), to develop new innovative solutions at design of system, component or processX
5Gain comprehensive information on modern techniques, methods and their borders which are being applied to engineeringX
6Ability to design and apply analytical, modelling and experimental based research, analyze and interpret the faced complex issues during the design and apply processX
7Gain high level ability to define the required information and dataX
8Ability to work in multi-disciplinary teams and to take responsibility to define approaches for complex situations
9Systematic and clear verbal or written transfer of the process and results of studies at national and international environmentsX
10Aware of social, scientific and ethical values guarding adequacy at all professional activities and at the stage of data collection, interpretation, and announcementX
11Aware of new and developing application of profession and ability to analyze and study on those applicationsX
12Ability to interpret engineering application’s social and environmental dimensions and it’s compliance with the social environment