Course Information
SemesterCourse Unit CodeCourse Unit TitleT+P+LCreditNumber of ECTS Credits
4MAK206Thermodynamics Iı3+0+035

Course Details
Language of Instruction Turkish
Level of Course Unit Bachelor's Degree
Department / Program Mechanical Engineering
Mode of Delivery Face to Face
Type of Course Unit Compulsory
Objectives of the Course 1. To teach basic principles and terminology of energy conversions,
2. To introduce fundamentals of thermal design of engineering systems,
3. To enhance the ability of analysis, application and communication in this field.
Course Content Clausius inequality. Entropy. Principle of the
increase of entropy. Exergy, second law analysis. Gas power cycles. Vapor power cycles. Refrigeration cycles, heat pump.
Course Methods and Techniques
Prerequisites and co-requisities None
Course Coordinator None
Name of Lecturers Asist Prof. Utku Cancı Matur
Assistants None
Work Placement(s) No

Recommended or Required Reading
Resources Çengel, Y. and Boles, M., “Thermodynamics, an Engineering Approach”,(Trans. T. Derbentli), McGraw-Hill and Literatür, İstanbul, 1996.
Lecturing
1 adet ödev, 1 adet yıliçi sınavı, 1 adet final

Course Category
Engineering %60
Engineering Design %30
Science %10

Planned Learning Activities and Teaching Methods
Activities are given in detail in the section of "Assessment Methods and Criteria" and "Workload Calculation"

Assessment Methods and Criteria
In-Term Studies Quantity Percentage
Mid-terms 1 % 40
Final examination 1 % 60
Total
2
% 100

 
ECTS Allocated Based on Student Workload
Activities Quantity Duration Total Work Load
Course Duration 14 3 42
Hours for off-the-c.r.stud 14 3 42
Mid-terms 1 10 10
Final examination 1 15 15
Total Work Load   Number of ECTS Credits 4 109

Course Learning Outcomes: Upon the successful completion of this course, students will be able to:
NoLearning Outcomes
1 Students who pass the course will be able to Apply basic principles and terminology of energy conversions
2 Students who pass the course will be able to Design basic thermal engineering systems
3 Students who pass the course will be able to Analyze, apply and communicate in this field
4 Students who pass the course will be able to Apply thermodynamic laws in concerned area
5 Students who pass the course will be able to Define the system in any problem.


Weekly Detailed Course Contents
WeekTopicsStudy MaterialsMaterials
1 Clausius inequality. Entropy. Principle of the increase of Entropy.
2 Third law of Thermodynamics. Entropy change of pure substance. Temperature-Entropy (T-s) diagram.
3 Entropy change of ideal gasses. Reversible steady flow work.
4 Adiabatic efficiency of some engines. Exergy and second law solution.
5 Second law solution of closed and open systems.
6 Power cycles with gas flow.
7 Otto and Diesel cycles. Brayton cycle.
8 Midterm exam
9 Brayton cycle with regeneration. Ideal jet propulsion cycles.
10 Vapor power cycles : Rankine cycle.
11 Ideal reheat Rankine cycle, Ideal regenerative Rankine cycle. Cogeneration.
12 Refrigeration cycles: Refrigerators and heat pumps.
13 Reversed Carnot cycle. Vapor compression refrigeration cycle.
14 Heat pump systems. Gas refrigeration cycle.
15 Ideal gas mixtures. Air-vapor mixture.
16 Final exam


Contribution of Learning Outcomes to Programme Outcomes
P1 P2 P3 P4 P5 P6 P7 P8 P9 P10 P11
All 5 5
C1
C2
C3
C4
C5

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https://obs.gedik.edu.tr/oibs/bologna/progCourseDetails.aspx?curCourse=205719&curProgID=73&lang=en