Code and Name of Course

 0502404 Thermodynamics II 

Type of Course

Compulsory

Prerequisite/Recommended 

None

Year/Semester of Course

2^nd Year / Spring Semester

Credit of Course

3 / 0 / 3

Coordinate of Course

Doç. Dr. Hüsamettin BULUT

Department

Mechanical Engineering

Instructors

Doç. Dr. Hüsamettin BULUT

Groups

One group

Objective of the Course

After completing the course, students will be able to apply the concept of exergy to qualitatively compare the quality of energy in various forms and perform an exergy analysis on common energy conversion devices using appropriate assumptions, understand how thermodynamic cycles are used in our society and be able to perform a quantitative cycle analysis, be able to develop and solve simple mathematical models of ideal gas mixtures undergoing a thermodynamic process and understand why these processes are important to our society, be able to use a limited set of thermodynamic property data and fundamental relations to calculate other thermodynamic properties, be able to develop and quantitatively analyze simple thermodynamic models of chemical reactions and understand the societal and environmental implications of combustion reactions, be able to develop and quantitatively analyze simple thermodynamic models for chemical equilibrium, be able to develop simpler computer models to perform and document thermodynamic analyses, be able to perform a thermodynamic analysis in a systematic manner and clearly document their work.

Course Contents

Irreversibility and availability. Vapor power and refrigeration cycles. Air standard power and refrigeration cycles. Thermodynamic relations. Ideal gas mixtures. Gas and vapor mixtures. Chemical reactions. Chemical equilibrium.

Textbook/Recommended

Reading

1-  Mühendislik Yaklaşımıyla Termodinamik,   Yunus A. Çengel ve Michael A. Boles,

2-  Mühendislikte Temel Termodinamik, Bülent Yeşilata.

3-Termodinamik Ders Notları, Hüsamettin Bulut.

4-  Termodinamik Problemleri, Aksel ÖZTÜRK ve Abdurrahman KILIÇ.

Plan of Course at Semester

 Week

  1) Entropy and the increase of entropy principle.

  2) The entropy change of pure substance.

  3) The entropy change of ideal gases.

  4) Property diagrams involving entropy. Isenrtopik processes. Tds relations.

  5) The reversible steady flow work and minimizing the compressing work.

  6) Gas power cycles. Reciprocatiing engine cycles: Otto and Diesel cycles.

  7) Midterm Exam

  8) The Carnot cycle. Air standart assumptions. Vapor cycles: The Rankine cycle.

 9) The Carnot cycle. Air standart assumptions. Vapor cycles: The Rankine cycle.(Continue)

11) Refrigeration cycles.

12) Refrigeration cycles (Continue).

13) Chemical Reactions

14) FINAL Exam

Form of Assessment

One written midterm exam (40%)

One written final exam (60%)