Education Information System

Course Title	Code	Semester	L+U Hour	Credits	ECTS
Thermodynamics	BSM205	3. Semester	3 + 0	3.0	4.0

Prerequisites

None

Language of Instruction	Turkish
Course Level	Undergraduate
Course Type
Mode of delivery	Face to face
Course Coordinator	Prof. Dr. Bekir ÇEVİK
Instructor(s)	Bekir ÇEVİK
Assistants
Goals	Teaching the knowledge that will form the basis of Thermodynamics topics in Biosystem Engineering
Course Content	Preliminaries Related to Thermodynamics and Thermodynamics Heat and heat sources, Heat transition Heat conduction, Heat transfer, Heat radiation Energy, First Law of Thermodynamics, Internal Energy and Enthalpy The First Law of Thermodynamics in Open Systems, The Inner Energy of Ideal Gases Change in Constant Temperature Second Law of Thermodynamics Cycles of Internal Combustion Engines, Two and Four Time Internal Explosion (Otto) Engines Cycles, cycles of two and four time internal combustion (diesel) engines Pure Substance and Thermodynamics of Pure Madden Pure Maddenin Status Changes Carnot cycle for power cycle High steam Rankine cycle.
Learning Outcomes	- Basic knowledge about Thermodynamics is obtained in Biosystem Engineering. - They obtain a basic knowledge of the concepts of heat and energy. - The thermodynamic laws are learned.

Week	Topics	Learning Methods
1. Week	Introduction to thermodynamics,	Course Hours Verbal Expression Visual Presentation
2. Week	Basic concepts of thermodynamics, units, international system of units (SI)	Verbal Expression Visual Presentation Course Hours
3. Week	Pure substances and gases, enthalpy, ideal gas laws, Avogadro's Law, Boyle-Moritte's Law, Charles-GayLussac's Law, Amagat's Law, Dalton's Law, Ideal gas equation of state	Course Hours Visual Presentation Verbal Expression
4. Week	Energy, Types of Energy, Zeroth and First Law of Thermodynamics	Course Hours Visual Presentation Verbal Expression
5. Week	Potential energy, kinetic energy, internal energy, enthalpy, sensible energy, latent energy, chemical energy, nuclear energy, mechanical energy	Course Hours Visual Presentation Verbal Expression
6. Week	Business concept, mechanical work, spindle work, electrical work, spring work	Course Hours Visual Presentation Verbal Expression
7. Week	Energy balance in closed systems, first law of thermodynamics, First Law analyzes in closed systems	Verbal Expression Course Hours Visual Presentation
8. Week	Midterm	Course Hours
9. Week	First Law analyzes of open systems	Verbal Expression Visual Presentation Course Hours
10. Week	Heat transfer , deat transfer by conduction, heat transfer by convection, heat transfer by radiation	Verbal Expression Visual Presentation Course Hours
11. Week	Principle of conservation of energy	Course Hours Verbal Expression Visual Presentation
12. Week	Energy conversion efficiencies	Visual Presentation Course Hours Verbal Expression
13. Week	II of thermodynamics. law and Carnot cycle	Visual Presentation Course Hours Verbal Expression
14. Week	Carnot cycle for power cycle, High steam Rankine cycle.	Visual Presentation Verbal Expression

1) K. Alibaş, Termodinamik I, Uludağ Üniversitesi Ziraat Fakültesi Yayını No:68, Bursa, 2010. 2) K. Alibaş, Termodinamik II, Uludağ Üniversitesi Ziraat Fakültesi Yayını No: 69, Bursa, 2010. 3) J.V.W. Gordon, R.E. Sonntag, Fundamentals of Classical Thermodynamic. J. Wiley and Sons İnc., 1976.

Program Requirements	Contribution Level	DK1	DK2	DK3	Measurement Method
PY1	4	4	4	4	40,60
PY2	4	4	4	4	40,60
PY3	5	5	5	5	40,60
PY4	5	5	5	5	40,60
PY5	4	4	4	4	40,60
PY6	4	4	4	4	40,60
PY7	4	4	4	4	40,60
PY8	4	4	4	4	40,60
PY9	4	4	4	4	40,60
PY10	4	4	4	4	40,60
PY11	3	3	3	3	40,60

*DK = Course's Contrubution.

	0	1	2	3	4	5
Course's Level of contribution	None	Very Low	Low	Fair	High	Very High
Method of assessment/evaluation		Written exam	Oral Exams	Assignment/Project	Laboratory work	Presentation/Seminar

Event	Quantity	Duration (Hour)	Total Workload (Hour)
Midterm 1	1	20	20
Homework 1	1	10	10
Final	1	30	30
Classroom Activities	14	3	42
Total Workload			102
ECTS Credit of the Course			25.5 4.0