FACULTY OF ENGINEERING

Department of Aerospace Engineering

ME 201 | Course Introduction and Application Information

Course Name
Engineering Thermodynamics
Code
Semester
Theory
(hour/week)
Application/Lab
(hour/week)
Local Credits
ECTS
ME 201
Spring
4
0
4
5

Prerequisites
None
Course Language
English
Course Type
Required
Course Level
First Cycle
Mode of Delivery -
Teaching Methods and Techniques of the Course Problem Solving
Application: Experiment / Laboratory / Workshop
Lecture / Presentation
Course Coordinator
Course Lecturer(s)
Assistant(s)
Course Objectives This course focuses on classical thermodynamics. Constructs the principles of thermodynamics such as mass, heat, energy, work, efficiency, ideal, and real thermodynamic cycles and processes. Covers open and closed systems, perfect gas law, and the first and second laws of thermodynamics with their applications in several engineering fields.
Learning Outcomes The students who succeeded in this course;
  • Explain the concepts of temperature, pressure and volume
  • Explain zeroth, first, second and third law of thermodynamics
  • Make the energy balances of open and closed systems
  • Analyze ideal and real thermodynamic cycles
  • Solve engineering problems using properties, property tables and the relationships of thermodynamics
Course Description The main topics included in this course are heat, work, kinetic theory of gasses, equation of state, thermodynamics system, control volume, first and second laws of thermodynamics, reversible and irreversible processes, introduction to basic thermodynamic cycles, system applications, entropy.

 



Course Category

Core Courses
Major Area Courses
Supportive Courses
Media and Management Skills Courses
Transferable Skill Courses

 

WEEKLY SUBJECTS AND RELATED PREPARATION STUDIES

Week Subjects Related Preparation
1 Basic concepts of temperature, temperature scales, pressure, and absolute and gage pressure and basic principles of thermodynamics such as system, state, state postulate, equilibrium, process, and cycle. Chapter 1 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
2 Introduction to concepts of energy, forms of energy, three mechanisms of heat transfer, work, first law, energy balances. Chapter 2 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
3 Pure substance and a discussion of the physics of phase-change processes. Demonstration the property tables and property diagrams. Chapter 3 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
4 The compressibility factor, the equations of van der Waals, Beattie-Bridgeman, and Benedict-Webb-Rubin. Chapter 3 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
5 The moving boundary work, the conservation of energy principle for closed systems, and development of the general energy balance applied to closed systems. Chapter 4 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
6 Specific Heats, specific heat at constant volume and the specific heat at constant pressure, internal energy and enthalpy change in incompressible substances Chapter 4 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
7 Conservation of mass principle, application of mass conservation to various systems, application the first law of conservation of energy principle to control volumes Chapter 5 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
8 Review and Midterm Exam
9 Steady flow processes, analysis of steady flow devices, energy balance to general unsteady-flow processes Chapter 5 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. BowlesChapter 6 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
10 The second law of thermodynamics, the valid processes as those satisfy both the first and second laws of thermodynamics, thermal energy reservoirs, reversible and irreversible processes Chapter 6 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
11 Carnot Cycle, Carnot principles, the idealized Carnot heat engines, refrigerators and heat pumps Chapter 6 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
12 Entropy to quantify the second-law effects, the increase of entropy principles, entropy changes in pure substances Chapter 7 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
13 Isentropic processes, the reversible steady-flow work Chapter 7 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
14 Isentropic efficiencies of various devices, entropy balance Chapter 7 Thermodynamics: An Engineering Approach by Yunus Çengel and Michael A. Bowles
15 Review of the semester
16 Final Exam

 

Course Notes/Textbooks

Yunus Çengel and Michael A. Bowles, Thermodynamics: An Engineering Approach, McGraw Hill Book Company, Ninth Edition, 2019.

Suggested Readings/Materials

Moran, MJ; Shapiro, HN; Boettner, DD; Bailey, MB, “Principles of Engineering Thermodynamics (8th edition), Wiley, Singapore    ISBN: 978-1-118-96088-2

 

 

EVALUATION SYSTEM

Semester Activities Number Weigthing
Participation
Laboratory / Application
Field Work
Quizzes / Studio Critiques
Portfolio
Homework / Assignments
1
20
Presentation / Jury
Project
Seminar / Workshop
Oral Exams
Midterm
1
40
Final Exam
1
40
Total

Weighting of Semester Activities on the Final Grade
2
60
Weighting of End-of-Semester Activities on the Final Grade
1
40
Total

ECTS / WORKLOAD TABLE

Semester Activities Number Duration (Hours) Workload
Theoretical Course Hours
(Including exam week: 16 x total hours)
16
4
64
Laboratory / Application Hours
(Including exam week: '.16.' x total hours)
16
0
Study Hours Out of Class
14
2
28
Field Work
0
Quizzes / Studio Critiques
0
Portfolio
0
Homework / Assignments
5
4
20
Presentation / Jury
0
Project
0
Seminar / Workshop
0
Oral Exam
0
Midterms
1
18
18
Final Exam
1
20
20
    Total
150

 

COURSE LEARNING OUTCOMES AND PROGRAM QUALIFICATIONS RELATIONSHIP

#
Program Competencies/Outcomes
* Contribution Level
1
2
3
4
5
1

To have theoretical and practical knowledge that have been acquired in the area of Mathematics, Natural Sciences, and Aerospace Engineering.

2

To be able to assess, analyze and solve problems by using the scientific methods in the area of Aerospace Engineering.

3

To be able to design a complex system, process or product under realistic limitations and requirements by using modern design techniques.

4

To be able to develop, select and use novel tools and techniques required in the area of Aerospace Engineering.

5

To be able to design and conduct experiments, gather data, analyze and interpret results.

6

To be able to develop communication skills, ad working ability in multidisciplinary teams.

7

To be able to communicate effectively in verbal and written Turkish; writing and understanding reports, preparing design and production reports, making effective presentations, giving and receiving clear and understandable instructions.

8

To have knowledge about global and social impact of engineering practices on health, environment, and safety; to have knowledge about contemporary issues as they pertain to engineering; to be aware of the legal ramifications of Aerospace Engineering solutions.

9

To be aware of professional and ethical responsibility; to have knowledge about standards utilized in engineering applications.

10

To have knowledge about industrial practices such as project management, risk management, and change management; to have awareness of entrepreneurship and innovation; to have knowledge about sustainable development.

11

To be able to collect data in the area of Aerospace Engineering, and to be able to communicate with colleagues in a foreign language (‘‘European Language Portfolio Global Scale’’, Level B1).

12

To be able to speak a second foreign language at a medium level of fluency efficiently.

13

To recognize the need for lifelong learning; to be able to access information, to be able to stay current with developments in science and technology; to be able to relate the knowledge accumulated throughout the human history to Aerospace Engineering.

*1 Lowest, 2 Low, 3 Average, 4 High, 5 Highest

 


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