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Information
| Unit | FACULTY OF ENGINEERING |
| MINING ENGINEERING PR. | |
| Code | MDZ205 |
| Name | Thermodynamics |
| Term | 2020-2021 Academic Year |
| Semester | 3. Semester |
| Duration (T+A) | 2-0 (T-A) (17 Week) |
| ECTS | 4 ECTS |
| National Credit | 2 National Credit |
| Teaching Language | Türkçe |
| Level | Lisans Dersi |
| Type | Normal |
| Label | C Compulsory |
| Mode of study | Uzaktan Öğretim |
| Catalog Information Coordinator | Prof. Dr. MAHMUT ALTINER |
| Course Instructor |
Prof. Dr. MAHMUT ALTINER
(Güz)
(A Group)
(Ins. in Charge)
|
Course Goal / Objective
To provide basic knowledge on fundamental thermodynamic theories releated with mineral processing, pyrometallurgy and hydrometallurgy
Course Content
Basic thermodynamic knowledge (work and energy-energy units, temperature, pressure, units and conversions) The zeroth and first law of thermodynamic (Enthalpy, temperature of compostion, heat, heat capacity and solution of examples) The second law of thermodynamic and entropy (spontaneous, irreversible and reversible processes) Behaviour of gases (ideal gas equation, mixture of gases and solution of example) Ideal and non-ideal solutions Gibbs free energy and chemical reactions (Gibbs-Helmholtz eqution, Gibb-Duhem equation and solution of example) Gibbs free energy and chemical reactions (calculation of free energy for chemical reactions) Gibbs free energy and chemical reactions (Free energy (G) - Temperature (T) diagrams- Ellingham diagram, Nernest eqution and Pourbaix diagram) Reaction kinetics and temperature (Arrhenius equation) Reaction kinetics and temperature (Calculation of activation energy, effect of temperature and solution of example) Reaction period (effects of surface area and catalysis, concentration-time curve) Electrochemistry (electrolysis cell dynamic) Electrochemistry (electrolysis and soltuion of example)
Course Precondition
Yok
Resources
Notes
Diğer Kaynaklar
Course Learning Outcomes
| Order | Course Learning Outcomes |
|---|---|
| LO01 | Understands basic thermodynamic theories for engineering |
| LO02 | Understands the basic approaches and applications on extractive metallurgy |
| LO03 | Understands the basic approaches and applications and chemical thermodynamic subjects |
| LO04 | Has the konwledge on the zeroth and first law of thermodynamic |
| LO05 | Has the konwledge on the second law of thermodynamic and entropy |
| LO06 | Has the konwledge on behaviour of gases (ideal gas equation, mixture of gases and solution |
| LO07 | Has the konwledge on the ideal and non-ideal solutions |
| LO08 | Has the konwledge on Gibbs free energy and chemical reactions |
| LO09 | Has the konwledge on the reaction kinetics and temperature (Arrhenius equation) |
| LO10 | Has the konwledge on reaction period (effects of surface area and catalysis, concentration-time curve) |
| LO11 | Has the konwledge on electrochemistry (electrolysis cell dynamic) |
| LO12 | Has the konwledge on the basic thermodynamic concepts (work and energy-energy units, temperature, pressure, units and conversions) |
Relation with Program Learning Outcome
| Order | Type | Program Learning Outcomes | Level |
|---|---|---|---|
| PLO01 | - | Students gain adequate knowledge about the engineering fields in the branches of mathematics, physical sciences or their own branches | 4 |
| PLO02 | - | Students use the theoretical and practical knowledge in mathematics, physical sciences and their fields for engineering solutions | 2 |
| PLO03 | - | Students choose and use the appropriate analytical mehtods and modelling techniques to identify, formulate, and solve the engineering problems | 4 |
| PLO04 | - | Students design and carry out experiments, collect data, analyze and interpret the results. | 4 |
| PLO05 | - | Students gain the capacity to analyze a system, a component, and desing the process under realistic constraints to meet the desired requirements; and the ability to apply the methods of modern design accordingly | 5 |
| PLO06 | - | Students choose and use the modern technical tools necessary for engineering practice. | 4 |
| PLO07 | - | Students gain the ability to work effectively both as an individual and in multi-disciplinary teams. | 3 |
| PLO08 | - | Students follow the current developments in their fields with a recognition of the need for lifelong learning and constantly improve themselves | 1 |
| PLO09 | - | Students use the resources of information and databases for the purpose of doing research and accesing information. | 2 |
| PLO10 | - | Students follow the scientific and technological developments in recognition of the need for lifelong learning, and continuously keep their knowledge up to date. | 2 |
| PLO11 | - | Students use the information and communication technologies together with the computer software at the level required by the European Computer Driving Licence. | 1 |
| PLO12 | - | Students use a foreign language according to the general level of European Language Portfolio B1 to communicate effectively in oral and written form. | 1 |
| PLO13 | - | Students gain the ability to communicate using technical drawing. | 1 |
| PLO14 | - | Students become informed of professional and ethical responsibility. | 2 |
| PLO15 | - | Students develop an awareness as regards project management, workplace practices, employee health, environmental and occupational safety; and the legal implications of engineering applications. | 1 |
| PLO16 | - | Students develop an awareness of the universal and social effects of engineering solutions and applications, the entrepreneurship and innovation subjects and gain knowledge of contemporary issues | 3 |
Week Plan
| Week | Topic | Preparation | Methods |
|---|---|---|---|
| 1 | Basic thermodynamic concepts (work and energy-energy units, temperature, pressure, units and conversions) | Literature research | |
| 2 | The zeroth and first law of thermodynamic (Enthalpy, temperature of compostion, heat, heat capacity and solution of examples) | Literature research | |
| 3 | The second law of thermodynamic and entropy (spontaneous, irreversible and reversible processes) | Literature research | |
| 4 | Behaviour of gases (ideal gas equation, mixture of gases and solution of example) I | Literature research | |
| 5 | Ideal and non-ideal solutions | Literature research | |
| 6 | Gibbs free energy and chemical reactions (Gibbs-Helmholtz eqution, Gibb-Duhem equation and solution of example) | Literature research | |
| 7 | Gibbs free energy and chemical reactions (calculation of free energy for chemical reactions) | Literature research | |
| 8 | First exam | ||
| 9 | Gibbs free energy and chemical reactions (Free energy (G) - Temperature (T) diagrams- Ellingham diagram, | Literature research | |
| 10 | Reaction kinetics and temperature (Arrhenius equation) | Literature research | |
| 11 | Reaction kinetics and temperature (Calculation of activation energy, effect of temperature ) | Literature research | |
| 12 | Reaction kinetics and temperature ( A solution of example) | Literature research | |
| 13 | Reaction period (effects of surface area and catalysis, concentration-time curve) | Literature research | |
| 14 | Electrochemistry (electrolysis cell dynamic) | Literature research | |
| 15 | Electrochemistry (electrolysis and soltuion of example) | Literature research | |
| 16 | Final exam | ||
| 17 | Final exam |
Assessment (Exam) Methods and Criteria
| Assessment Type | Midterm / Year Impact | End of Term / End of Year Impact |
|---|---|---|
| 1. Midterm Exam | 100 | 40 |
| General Assessment | ||
| Midterm / Year Total | 100 | 40 |
| 1. Final Exam | - | 60 |
| Grand Total | - | 100 |
Student Workload - ECTS
| Works | Number | Time (Hour) | Workload (Hour) |
|---|---|---|---|
| Course Related Works | |||
| Class Time (Exam weeks are excluded) | 14 | 2 | 28 |
| Out of Class Study (Preliminary Work, Practice) | 14 | 2 | 28 |
| Assesment Related Works | |||
| Homeworks, Projects, Others | 1 | 0 | 0 |
| Mid-term Exams (Written, Oral, etc.) | 1 | 8 | 8 |
| Final Exam | 1 | 24 | 24 |
| Total Workload (Hour) | 88 | ||
| Total Workload / 25 (h) | 3,52 | ||
| ECTS | 4 ECTS | ||