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| Course Description |
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| Course Name |
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Thermodynamics II |
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| Course Code |
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ME 210 |
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| Course Type |
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Compulsory |
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| Level of Course |
: |
First Cycle |
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| Year of Study |
: |
2 |
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| Course Semester |
: |
Spring (16 Weeks) |
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| ECTS |
: |
5 |
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| Name of Lecturer(s) |
: |
Assoc.Prof.Dr. ALPER YILMAZ
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| Learning Outcomes of the Course |
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Learns the definition of entropy and entropy balance in closed and open systems
Learns gas power cycles
Learns vapor and combined power cycles
Learns vapor compression refrigeration cycles, refrigerants and heat pumps
Learns gas refrigeration cycles and absorption refrigeration cycles
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| Mode of Delivery |
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Face-to-Face |
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| Prerequisites and Co-Prerequisites |
: |
None |
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| Recommended Optional Programme Components |
: |
None |
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| Aim(s) of Course |
: |
To educate students in order to analyse power and refrigeration cycles, to determine thermodynamic properties and to calculate air-conditioning processes and thereby to solve related engineering problems. |
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| Course Contents |
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Power cycles. Refrigeration cycles. Air-conditioning processes. |
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| Language of Instruction |
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English |
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| Work Place |
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Classroom |
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Course Outline /Schedule (Weekly) Planned Learning Activities |
| Week | Subject | Student's Preliminary Work | Learning Activities and Teaching Methods |
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1 |
Definition of Entropy, entropy balance in closed and open systems |
Reading of lecture notes |
Conceptual and mathematical education |
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2 |
T ds relations, entropy change of pure substances
|
Reading of lecture notes |
Conceptual and mathematical education |
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3 |
Isentropic processes
|
Reading of lecture notes |
Conceptual and mathematical education |
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4 |
Reversible steady flow work, minimizing the compressor work, isentropic efficiencies of steady flow devices |
Reading of lecture notes |
Conceptual and mathematical education |
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5 |
Classification of thermodynamic cycles, gas power cycles, air-standard assumptions |
Reading of lecture notes |
Conceptual and mathematical education |
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6 |
Otto, Diesel, Sterling cycles |
Reading of lecture notes |
Conceptual and mathematical education |
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7 |
Ericson and Brayton cycles |
Reading of lecture notes |
Conceptual and mathematical education |
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8 |
Turbojet, turbofan and turboprob engines |
Reading of lecture notes |
Conceptual and mathematical education |
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9 |
Vapor and combined power cycles, Rankine cycle |
Reading of lecture notes |
Conceptual and mathematical education |
|
10 |
Mid-term exam |
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|
11 |
Ideal reheat Rankine cycle and ideal regenerative Rankine cycle
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Reading of lecture notes |
Conceptual and mathematical education |
|
12 |
An introduction to refrigeration, ideal and actual vapor compression refrigeration cycles, refrigerants, heat pump systems |
Reading of lecture notes |
Conceptual and mathematical education |
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13 |
Innovative vapor compression refrigeration systems |
Reading of lecture notes |
Conceptual and mathematical education |
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14 |
Gas refrigeration cycles and absorption refrigeration cycles |
Reading of lecture notes |
Conceptual and mathematical education |
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15 |
Final exam |
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Required Course Resources |
| Resource Type | Resource Name |
| Recommended Course Material(s) |
 Lecture notes
Thermodynamics, an engineering approach, Yunus Çengel
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| |
| Required Course Material(s) | |
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Assessment Methods and Assessment Criteria |
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Semester/Year Assessments |
Number |
Contribution Percentage |
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Mid-term Exams (Written, Oral, etc.) |
2 |
30 |
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Homeworks/Projects/Others |
4 |
70 |
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Total |
100 |
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Rate of Semester/Year Assessments to Success |
40 |
| |
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Final Assessments
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100 |
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Rate of Final Assessments to Success
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60 |
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Total |
100 |
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| Contribution of the Course to Key Learning Outcomes |
| # | Key Learning Outcome | Contribution* |
|
1 |
Students gain a command of basic concepts, theories and principles in mechanical engineering |
4 |
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2 |
Student become equipped with the basic knowledge of math, science and engineering |
5 |
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3 |
Students are able to design and carry out experiments in the basic fields of mechanical engineering, and interpret the results and the data obtained from the experiments |
3 |
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4 |
Students become equipped with a variety of skills and knowledge regarding engineering techniques |
4 |
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5 |
Students are able to design a system, component or process in order to meet the needs of various engineering problems within technical, economic, environmental, manufacturability, and sustainability limits. |
5 |
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6 |
Students independently review and learn the applications in an enterprise, make a critical assessment of the problems faced with, formulate problems and propose solutions by selecting the proper technique |
4 |
|
7 |
Students take initiative in identification, design, development and use of a product or production process. |
4 |
|
8 |
Students become aware of the necessity of lifelong learning and continuously self-renew |
4 |
|
9 |
Students use English effectively for technical or non-technical topics orally or in wirtten form. |
2 |
|
10 |
Students become effective in using computer, computer-aided drafting, design, analysis, and presentation |
2 |
|
11 |
Students have good communicatino skills with a tendency to work in teams, and are able to work effectively as a member of an interdisciplinary team |
4 |
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12 |
Students become aware of the technical and ethical responsibilities, as well as being inquisitive and innovative |
3 |
| * Contribution levels are between 0 (not) and 5 (maximum). |
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| Student Workload - ECTS |
| Works | Number | Time (Hour) | Total Workload (Hour) |
| Course Related Works |
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Class Time (Exam weeks are excluded) |
14 |
3 |
42 |
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Out of Class Study (Preliminary Work, Practice) |
14 |
3 |
42 |
| Assesment Related Works |
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Homeworks, Projects, Others |
4 |
4 |
16 |
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Mid-term Exams (Written, Oral, etc.) |
2 |
5 |
10 |
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Final Exam |
1 |
5 |
5 |
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Total Workload: | 115 |
| Total Workload / 25 (h): | 4.6 |
| ECTS Credit: | 5 |
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