GAZI UNIVERSITY INFORMATION PACKAGE - 2019 ACADEMIC YEAR

COURSE DESCRIPTION
THERMODYNAMICS/ETM-311
Course Title: THERMODYNAMICS
Credits 3 ECTS 3
Course Semester 5 Type of The Course Compulsory
COURSE INFORMATION
 -- (CATALOG CONTENT)
 -- (TEXTBOOK)
 -- (SUPPLEMENTARY TEXTBOOK)
 -- (PREREQUISITES AND CO-REQUISITES)
 -- LANGUAGE OF INSTRUCTION
  Turkish
 -- COURSE OBJECTIVES
 -- COURSE LEARNING OUTCOMES
Will be able to explain basic thermodynamic concepts like open, closed and isolated systems
Will be able to explain the state of a system in equilibrium and the properties of a system in equilibrium
Will be able to define thermodynamic properties, phase diagrams and phase transitions of pure substances
Will be able to explain energy transfer through heat and work transfer
Will be able to explain the first thermodynamic law, energy conservation in closed systems, energy used in energy conversion
Will be able to explain the second thermodynamic law and job loss
Will be able to explain energy conversion devices and machines (compressors, turbines, boilers, heat exchangers, combustion cells, etc.)
Will be able to explain thermodynamic cycles and analyze them
Will be able to apply engineering system calculations and designs, apply the laws of thermodynamics in related fields, solve related problems
 -- MODE OF DELIVERY
  The mode of delivery of this course is face to face Expression, practice
 --WEEKLY SCHEDULE
1. Week  Basic concepts and definitions. Dimensions and units. Properties of Systems. State and equilibrium. State change and cycles. Pressure. Temperature. The Zeroth
2. Week  Pure substance and properties. Phases of pure substance and phase change. Properties diagrams and tables.
3. Week  Ideal gas and equation of state. Real gasses. Compressibility factor. Generalized chart for Compressibility factor. Other equations of state. Introduction to the first law of thermodynamics.
4. Week  1st law of thermodynamics (for closed systems). Heat and work. Specific heats. Internal energy, enthalpy, specific heat of ideal gasses. Specific heat of solids and liquids.
5. Week  First law of Thermodynamics (for open systems). Conservation of mass. Conservation of energy. Flow work. Open systems with steady flow.
6. Week  Unsteady open systems. The uniform-state, uniform-flow systems. Second law of Thermodynamics. Heat engines. Refrigeration systems and heat pumps.
7. Week  Reversible and irreversible processes. Carnot cycles. Carnot principles. The thermodynamic temperature scale.
8. Week  Clausius inequality. Entropy. Principle of the increase of Entropy. Third law of Thermodynamics. Entropy change of pure substance. Temperature-Entropy (T-s) diagram.
9. Week  Entropy change of ideal gasses. Reversible steady flow work. Adiabatic efficiency of some engines. Exergy and second law solution.
10. Week  Second law solution of closed and open systems. Power cycles with gas flow: Air standard assumptions.
11. Week  Otto and Diesel cycles. Brayton cycle. Brayton cycle with regeneration. Ideal jet propulsion cycles. Vapor power cycles: Rankine cycle. Ideal reheat Rankine cycle, Ideal regenerative Rankine cycle. Cogeneration.
12. Week  Refrigeration cycles: Refrigerators and heat pumps. Reversed Carnot cycle. Vapor compression refrigeration cycle. Heat pump systems. Gas refrigeration cycle.
13. Week  Ideal gas mixtures. Air-vapor mixture.
14. Week  Applications.
15. Week  
16. Week  
 -- TEACHING and LEARNING METHODS
 -- ASSESSMENT CRITERIA
 
Quantity
Total Weighting (%)
 Midterm Exams
1
40
 Assignment
1
20
 Application
0
0
 Projects
0
0
 Practice
0
0
 Quiz
0
0
 Percent of In-term Studies  
60
 Percentage of Final Exam to Total Score  
40
 -- WORKLOAD
 Activity  Total Number of Weeks  Duration (weekly hour)  Total Period Work Load
 Weekly Theoretical Course Hours
14
3
42
 Weekly Tutorial Hours
0
 Reading Tasks
0
 Searching in Internet and Library
6
3
18
 Material Design and Implementation
1
3
3
 Report Preparing
0
 Preparing a Presentation
0
 Presentation
0
 Midterm Exam and Preperation for Midterm Exam
2
3
6
 Final Exam and Preperation for Final Exam
2
3
6
 Other (should be emphasized)
0
 TOTAL WORKLOAD: 
75
 TOTAL WORKLOAD / 25: 
3
 Course Credit (ECTS): 
3
 -- COURSE'S CONTRIBUTION TO PROGRAM
NO
 PROGRAM LEARNING OUTCOMES
1
2
3
4
5
1Adequate knowledge in mathematics, science and engineering subjects pertaining to the relevant discipline; ability to use theoretical and applied information in these areas to model and solve engineering problems.X
2Ability to identify, formulate, and solve complex engineering problems; ability to select and apply proper analysis and modeling methods for this purpose.X
3Ability to design a complex system, process, device or product under realistic constraints and conditions, in such a way as to meet the desired result; ability to apply modern design methods for this purpose.X
4Ability to develop, select and use modern techniques and tools necessary for analysis and solution of complex problems in engineering applications; ability to use information technologies effectively.X
5Ability to design and conduct experiments, gather data, analyze and interpret results for examination of engineering problems or discipline-specific research topics.X
6Ability to work efficiently in intra-disciplinary teams.X
7Ability to work efficiently in multi-disciplinary teams.X
8Ability to communicate effectively in Turkish, both orally and in writing; knowledge of a minimum of one foreign language.X
9Ability to write effective reports and understand written reports, to prepare design and production reports, to make effective presentations, to give clear and understandable instructions and to receive.X
10Recognition of the need for lifelong learning; ability to access information, to follow developments in science and technology, and to continue to educate him/herself.X
11Conformity to ethical principles, professional and ethical responsibility; Information on standards used in engineering applications.X
12Knowledge on practices in business, such as project management, risk management and change management.X
13Knowledge about awareness of entrepreneurship, innovation, and sustainable development.X
14Knowledge about contemporary issues and the global and societal effects of engineering practices on health, environment, and safety.X
15Knowledge about awareness of the legal consequences of engineering solutions.X
 -- NAME OF LECTURER(S)
   ( Prof. Dr. Veysel Özdemir )
 -- WEB SITE(S) OF LECTURER(S)
   (https://websitem.gazi.edu.tr/site/vozdemir)
 -- EMAIL(S) OF LECTURER(S)
   ( vozdemir@gazi.edu.tr)