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SDÜ Education Information System Course Content
Programme
Graduate School of Natural and Applied Sciences Mechanical Engineering
Course Information
Course Unit Code
Course Unit Title
Credit Theoretic
Credit Pratic
Credit Lab/A
Credit Total
Credit Ects
Semester
01MAK5116
Advanced Thermodynamics
3.00
0.00
0.00
3.00
6.00
1
Course Information
Language of Instruction
Turkish
Type of Course Unit
Elective
Course Coordinator
Associate Professor Dr. Ali BOLATTÜRK
Course Instructors
 
Course Assistants
 
Course Aims
To remind basic concepts of thermodynamics, to learn the advanced subjects of thermodynamics; the students gain some information about specific subjects and their interactive relations, which will be necessary to know for their thesis work
Course Goals
To gain knowledge about specific and advanced subjects of Thermodynamics
To gain some information for engineering applications of Thermodynamics
To know the thermodynamically solutions of physical and chemical processes, and their interactive relations
To gain the calculation methods of combined energy and mass balance equations for Thermodynamic equilibrium
Emphasis is placed on the relationship of thermodynamics to the broad fields of engineering and applied science
Learning Outcomes of The Course Unit
To gain knowledge about specific and advanced subjects of Thermodynamics
To gain some information for engineering applications of Thermodynamics
To know the thermodynamically solutions of physical and chemical processes, and their interactive relations
To gain the calculation methods of combined energy and mass balance equations for Thermodynamic equilibrium
Emphasis is placed on the relationship of thermodynamics to the broad fields of engineering and applied science
Course Contents
Basic concepts of thermodynamics, The first, second and third laws of thermodynamics, Reversibility-irreversibility, Second law analysis of engineering systems, Application of thermodynamics laws to engineering systems and flow processes, Maxwell relations, Thermodynamics of chemical reactions, Chemical equilibrium, Phase equilibrium, Thermodynamics of high speed gas flow,
Prerequisities and Co-requisities Courses
 
Recommended Optional Programme Components
 
Mode Of Delivery
 
Level of Course Unit
 
Assessment Methods and Criteria
ECTS / Table Of Workload (Number of ECTS credits allocated)
Studies During Halfterm
Number
Co-Efficient
Activity
Number
Duration
Total
Visa
1
70
Course Duration (Excluding Exam Week)
14
3
42
Quiz
0
0
Time Of Studying Out Of Class
14
3
42
Homework
2
20
Homeworks
2
18
36
Attendance
0
0
Presentation
0
0
0
Application
0
0
Project
0
0
0
Lab
0
0
Lab Study
0
0
0
Project
0
0
Field Study
0
0
0
Workshop
0
0
Visas
1
22
22
Seminary
0
0
Finals
1
26
26
Field study
0
0
Workload Hour (30)
30
TOTAL
90
Total Work Charge / Hour
168
The ratio of the term to success
50
Course's ECTS Credit
6
The ratio of final to success
50
 
TOTAL
100
 
Recommended or Required Reading
Textbook
 
Additional Resources
K. Wark, Advanced Thermodynamics for Engineers, McGraw-Hill, 1995.
Y.Cengel, M.A. Boles, Thermodynamics: An Engineering Approach, 5th Ed., Güven Bilimsel, 2008.
E.D. Winterbone, Advanced Thermodynamics for Engineers, Butterworth Heinemann,1997
Material Sharing
Documents
 
Assignments
 
Exams
 
Additional Material
 
Planned Learning Activities and Teaching Methods
Lectures, Practical Courses, Presentation, Seminar, Project, Laboratory Applications (if necessary)
Work Placements
As with any other educational component, credits for work placements are only awarded when the learning outcomes have been achieved and assessed. If a work placement is part of organised mobility (such as Farabi and Erasmus), the Learning Agreement for the placement should indicate the number of credits to be awarded if the expected learning outcomes are achieved.
Program Learning Outcomes
No
Course's Contribution to Program
Contribution
Course Content