Courses offered by Mechanical Power Engineering Department
The Mechanical Power Engineering Department is responsible for teaching courses that serve the following programs:
- Several Basic Mechanical Engineering courses as a Mechanical Discipline Requirement.
- Mechanical Power Engineering Program.
- Design and Production Engineering Program
- Automotive Engineering Program
- Mechatronics Engineering Program
- Materials Engineering Program
- Manufacturing Engineering Program
- Mechatronics Engineering and Automation Program
- Energy and Renewable Energy Engineering Program.
- Architectural Engineering Program.
- Electrical Power and Machines Engineering Program
- Landscape Architecture Program
- Housing Architecture and Urban Development Program
- Building Engineering Program
Table 46 List of specializations at the Design and Production Engineering Department.
# | Specialization |
1 | Power generation |
2 | Energy Efficiency and Sustainability |
3 | Process and Equipment Design |
4 | Environment, Services and Systems |
5 | Nuclear Energy Technology |
6 | Graduation Projects |
The following abbreviations are the legend for the courses table.
Lvl | Level | UR | University Requirement | SA | Student Activities | ||
CH | Credit Hour | FR | Faculty Requirement | MT | Mid-Term Exam | ||
ECTS | European Credit Transfer System | DR | Discipline Requirement | PE | Practical Exam | ||
SWL | Student Work Load | PR | Program Requirement | FE | Final Exam | ||
Lec | Lectures | ||||||
Tut | Tutorials | ||||||
Lab | Laboratory | ||||||
TT | Total |
Table 47 List of MEP courses.
# | Lvl | Code | Course Title | Credits and SWL | Contact Hours | Classification | Assessment (%) | Prerequisites | ||||||||||||
CH | ECTS | SWL | Lec | Tut | Lab | TT | UR | FR | DR | PR | SA | MT | PE | FE | ||||||
1 | MEP214 | Thermal Power Engineering | 3 | 0 | 0 | 0 | 0 | 15 | 25 | 10 | 40 | |||||||||
1 | MEP214s | Thermal Power Engineering | 3 | 0 | 0 | 0 | 0 | 25 | 25 | 50 | ||||||||||
1 | MEP446 | Refrigerators and AC Systems and Equipment | 0 | 0 | 0 | 0 | 0 | 15 | 25 | 10 | 40 | |||||||||
1 | MEP446s | Refrigerators and AC Systems and Equipment | 0 | 0 | 0 | 0 | 0 | 0 | ||||||||||||
1. Power generation | ||||||||||||||||||||
1 | 1 | MEP111 | Thermal Physics | 2 | 4 | 100 | 1 | 2 | 0 | 3 | x | 30 | 25 | 0 | 40 | |||||
1 | 1 | MEP111s | Thermal Physics | 2 | 4 | 100 | 1 | 2 | 0 | 3 | x | 35 | 25 | 0 | 40 | |||||
1 | 1 | MEP112 | Thermal Power Engineering | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( PHM041 ) AND ( PHM022 ) | ||||
1 | 1 | MEP112s | Thermal Power Engineering | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 25 | 25 | 0 | 50 | ( PHM041s ) AND ( PHM022s ) | ||||
1 | 2 | MEP211 | Thermodynamics | 4 | 6 | 150 | 3 | 2 | 1 | 6 | x | 30 | 25 | 0 | 40 | ( MEP111 ) | ||||
1 | 2 | MEP211s | Thermodynamics | 4 | 6 | 150 | 3 | 2 | 1 | 6 | x | 25 | 25 | 10 | 40 | ( MEP111s ) | ||||
1 | 2 | MEP212 | Heat Transfer | 4 | 8 | 200 | 2 | 2 | 3 | 7 | x | 15 | 25 | 15 | 40 | ( MEP211 ) | ||||
1 | 2 | MEP212s | Heat Transfer | 4 | 8 | 200 | 2 | 2 | 3 | 7 | x | 20 | 25 | 15 | 40 | ( MEP211s ) | ||||
1 | 2 | MEP213 | Thermal Analysis of Buildings | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( PHM012 ) | ||||
1 | 2 | MEP213s | Thermal Analysis of Buildings | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( PHM012s ) | ||||
1 | 3 | MEP311 | Combustion | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 15 | 25 | 15 | 40 | ( MEP212 ) | ||||
1 | 3 | MEP311s | Combustion | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP212s ) | ||||
1 | 3 | MEP312 | Fundamentals of Internal Combustion Engines | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 15 | 40 | ( MEP212 ) | ||||
1 | 3 | MEP312s | Fundamentals of Internal Combustion Engines | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP212s ) | ||||
1 | 3 | MEP313 | Thermal Power Plants | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 15 | 40 | ( MEP212 ) | ||||
1 | 3 | MEP313s | Thermal Power Plants | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP212s ) | ||||
1 | 3 | MEP314 | Power Plant Technology | 4 | 7 | 175 | 3 | 2 | 0 | 5 | x | 15 | 25 | 10 | 40 | ( MEP313 ) | ||||
1 | 3 | MEP314s | Power Plant Technology | 4 | 7 | 175 | 3 | 2 | 0 | 5 | x | 35 | 25 | 0 | 40 | ( MEP313s ) | ||||
1 | 4 | MEP411 | Control Systems of Internal Combustion Engines | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MEP312 ) | ||||
1 | 4 | MEP411s | Control Systems of Internal Combustion Engines | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP312s ) | ||||
1 | 4 | MEP412 | Heat Engines | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 4 | MEP412s | Heat Engines | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP413 | Gas Fueled Engines | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP312 ) | ||||
1 | 4 | MEP413s | Gas Fueled Engines | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP312s ) | ||||
1 | 4 | MEP414 | Biomass and Waste Conversion Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP212 ) AND ( MEP311 ) | ||||
1 | 4 | MEP414s | Biomass and Waste Conversion Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP311s ) | ||||
2. Energy Efficiency and Sustainability | ||||||||||||||||||||
1 | 2 | MEP221 | Fluid Mechanics and Turbo-Machinery | 4 | 7 | 175 | 3 | 2 | 1 | 6 | x | 15 | 25 | 15 | 40 | ( PHM113 ) | ||||
1 | 2 | MEP221s | Fluid Mechanics and Turbo-Machinery | 4 | 7 | 175 | 3 | 2 | 1 | 6 | x | 20 | 25 | 15 | 40 | ( PHM112s ) | ||||
1 | 2 | MEP222 | Introduction to Fluid Mechanics | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 30 | 25 | 0 | 40 | |||||
1 | 2 | MEP222s | Introduction to Fluid Mechanics | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP111s ) | ||||
1 | 3 | MEP321 | Incompressible Flow Machines | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 15 | 25 | 15 | 40 | ( MEP221 ) | ||||
1 | 3 | MEP321s | Incompressible Flow Machines | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP221s ) | ||||
1 | 3 | MEP322 | Compressible Flow Machines | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 15 | 25 | 15 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 3 | MEP322s | Compressible Flow Machines | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP421 | Sustainable Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) | ||||
1 | 4 | MEP421s | Sustainable Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) | ||||
1 | 4 | MEP422 | Energy Storage Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP313 ) | ||||
1 | 4 | MEP422s | Energy Storage Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP313s ) | ||||
1 | 4 | MEP423 | Hydro-Tidal and Wave Energies | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP321 ) | ||||
1 | 4 | MEP423s | Hydro-Tidal and Wave Energies | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP321s ) | ||||
1 | 4 | MEP424 | Water Distribution Networks | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP321 ) | ||||
1 | 4 | MEP424s | Water Distribution Networks | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP321s ) | ||||
1 | 4 | MEP425 | Aircraft Propulsion | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP311 ) AND ( MEP322 ) | ||||
1 | 4 | MEP425s | Aircraft Propulsion | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP311s ) AND ( MEP322s ) | ||||
1 | 4 | MEP426 | Solar Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP212 ) | ||||
1 | 4 | MEP426s | Solar Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) | ||||
1 | 4 | MEP427 | Wind Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP322 ) | ||||
1 | 4 | MEP427s | Wind Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP322s ) | ||||
1 | 4 | MEP428 | Hydraulic Transmission | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP221 ) AND ( MEP321 ) | ||||
1 | 4 | MEP428s | Hydraulic Transmission | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP221s ) AND ( MEP321s ) | ||||
3. Process and Equipment Design | ||||||||||||||||||||
1 | 2 | MEP231 | Measurement and Instrumentation | 2 | 5 | 125 | 1 | 0 | 3 | 4 | x | 15 | 25 | 15 | 40 | |||||
1 | 2 | MEP231s | Measurement and Instrumentation | 2 | 5 | 125 | 1 | 0 | 3 | 4 | x | 20 | 25 | 15 | 40 | |||||
1 | 3 | MEP331 | Digital Control | 2 | 4 | 100 | 2 | 0 | 1 | 3 | x | 15 | 25 | 10 | 40 | ( MCT211 ) | ||||
1 | 3 | MEP331s | Digital Control | 2 | 4 | 100 | 2 | 0 | 1 | 3 | x | 20 | 25 | 15 | 40 | ( MCT211s ) | ||||
1 | 3 | MEP332 | Process Control | 3 | 7 | 175 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MEP331 ) | ||||
1 | 3 | MEP332s | Process Control | 3 | 7 | 175 | 2 | 2 | 1 | 5 | x | 20 | 25 | 15 | 40 | ( MEP331s ) | ||||
1 | 4 | MEP431 | Fire Fighting | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 4 | MEP431s | Fire Fighting | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP432 | Computational Fluid Dynamics | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 4 | MEP432s | Computational Fluid Dynamics | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP433 | Management of Mechanical Power Projects | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP314 ) | ||||
1 | 4 | MEP433s | Management of Mechanical Power Projects | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP314s ) | ||||
1 | 4 | MEP434 | Water Desalination and Distillation | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP212 ) | ||||
1 | 4 | MEP434s | Water Desalination and Distillation | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) | ||||
1 | 4 | MEP435 | Design of Mechanical Power Units | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MDP211 ) AND ( MDP212 ) | ||||
1 | 4 | MEP435s | Design of Mechanical Power Units | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP211s ) AND ( MDP212s ) | ||||
4. Environment, Services and Systems | ||||||||||||||||||||
1 | 2 | MEP241 | Technical Installations | 2 | 3 | 75 | 1 | 2 | 0 | 3 | x | 15 | 25 | 15 | 40 | |||||
1 | 2 | MEP241s | Technical Installations | 2 | 3 | 75 | 1 | 2 | 0 | 3 | x | 20 | 25 | 15 | 40 | |||||
1 | 3 | MEP341 | Refrigeration and Air Conditioning | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP212 ) AND (MEP221) | ||||
1 | 3 | MEP341s | Refrigeration and Air Conditioning | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 3 | MEP342 | HVAC System Design | 2 | 5 | 125 | 2 | 1 | 0 | 3 | x | 30 | 25 | 0 | 40 | ( MEP213 ) | ||||
1 | 3 | MEP342s | HVAC System Design | 2 | 5 | 125 | 2 | 1 | 0 | 3 | x | 35 | 25 | 0 | 40 | ( MEP213s ) | ||||
1 | 4 | MEP441 | Applied Building Services Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 4 | MEP441s | Applied Building Services Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP442 | Thermodynamics of Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP221 ) AND ( MEP321 ) | ||||
1 | 4 | MEP442s | Thermodynamics of Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP221s ) AND ( MEP321s ) | ||||
1 | 4 | MEP443 | Petroleum Pipelines | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 4 | MEP443s | Petroleum Pipelines | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP444 | Economics of Energy Conversion | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 4 | MEP444s | Economics of Energy Conversion | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP445 | Environmental Impact of Mechanical Power Projects | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP342 ) | ||||
1 | 4 | MEP445s | Environmental Impact of Mechanical Power Projects | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
5. Nuclear Energy Technology | ||||||||||||||||||||
1 | 4 | MEP451 | Nuclear Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) AND ( MEP221 ) | ||||
1 | 4 | MEP451s | Nuclear Energy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MEP221s ) | ||||
1 | 4 | MEP452 | Thermal Aspects of Nuclear Reactors | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) | ||||
1 | 4 | MEP452s | Thermal Aspects of Nuclear Reactors | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) | ||||
1 | 4 | MEP453 | Nuclear Reactions and Interaction with Matter | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP211 ) | ||||
1 | 4 | MEP453s | Nuclear Reactions and Interaction with Matter | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP211s ) | ||||
1 | 4 | MEP454 | Radioactive Waste Management | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP212 ) | ||||
1 | 4 | MEP454s | Radioactive Waste Management | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) | ||||
1 | 4 | MEP455 | Methods of Nuclear Risk Analysis | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MEP314 ) | ||||
1 | 4 | MEP455s | Methods of Nuclear Risk Analysis | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP314s ) | ||||
9. Graduation Project | ||||||||||||||||||||
1 | 4 | MEP491 | Mechanical Power Graduation Project (1) | 3 | 7 | 175 | 1 | 2 | 4 | 7 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MEP491s | Mechanical Power Graduation Project (1) | 3 | 7 | 175 | 1 | 2 | 4 | 7 | x | 60 | 0 | 0 | 40 | |||||
1 | 4 | MEP492 | Mechanical Power Graduation Project (2) | 3 | 7 | 175 | 1 | 2 | 4 | 7 | x | 15 | 25 | 10 | 40 | ( MEP491 ) | ||||
1 | 4 | MEP492s | Mechanical Power Graduation Project (2) | 3 | 7 | 175 | 1 | 2 | 4 | 7 | x | 35 | 25 | 0 | 40 | ( MEP491s ) |
MEP214 | Thermal Power Engineering | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
0 Hours | 0 Hours | 0 Hours | |||||||||
Required SWL | Equivalent ECTS | ||||||||||
Course Content | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechatronics Engineering and Automation |
2 | 3 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP214s | Thermal Power Engineering | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
0 Hours | 0 Hours | 0 Hours | |||||||||
Required SWL | Equivalent ECTS | ||||||||||
Course Content | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | % | 50% |
MEP446 | Refrigerators and AC Systems and Equipment | 0 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
0 Hours | 0 Hours | 0 Hours | |||||||||
Required SWL | Equivalent ECTS | ||||||||||
Course Content | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP446s | Refrigerators and AC Systems and Equipment | 0 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
0 Hours | 0 Hours | 0 Hours | |||||||||
Required SWL | Equivalent ECTS | ||||||||||
Course Content | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
% | % | % | 0% |
MEP111 | Thermal Physics | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Thermal System, Control Volume, States of the Working Medium, Processes and Cycles, Calculation of Work, Heat Exchange with the Surroundings, Ideal Gases, Specific Heat at Constant Volume, Specific Heat at Constant Pressure, Equation of State, Pure Substances, Phase Equilibrium, Tables of Thermodynamic Properties, Internal Energy, Enthalpy, First Law of Thermodynamics on Closed Systems, First Law of Thermodynamics on Steady State Steady Flow Open Systems, The Case of Uniform State Uniform Flow, Application on Reciprocating Compressors, Ideal Gas Mixtures. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
1 | 3 | |||||||||
Energy and Renewable Energy Engineering |
1 | 3 | |||||||||
Materials Engineering |
1 | 3 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP111s | Thermal Physics | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Thermal System, Control Volume, States of the Working Medium, Processes and Cycles, Calculation of Work, Heat Exchange with the Surroundings, Ideal Gases, Specific Heat at Constant Volume, Specific Heat at Constant Pressure, Equation of State, Pure Substances, Phase Equilibrium, Tables of Thermodynamic Properties, Internal Energy, Enthalpy, First Law of Thermodynamics on Closed Systems, First Law of Thermodynamics on Steady State Steady Flow Open Systems, The Case of Uniform State Uniform Flow, Application on Reciprocating Compressors, Ideal Gas Mixtures. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
1 | ||||||||||
Design and Production Engineering |
3 | ||||||||||
Mechanical Power Engineering |
3 | ||||||||||
Automotive Engineering |
3 | ||||||||||
Mechatronics Engineering |
3 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP112 | Thermal Power Engineering | 3 CH | |||||||||
Prerequisites | ( PHM041 ) AND ( PHM022 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Thermal System, Control Volume, States of the Working Medium, Processes and Cycles, Calculation of Work, Heat Exchange with the Surroundings, Ideal Gases, Equation of State, Pure Substances, Phase Equilibrium, Tables of Thermodynamic Properties, First Law of Thermodynamics on Steady State Steady Flow Open Systems, and Applications such as simple Steam Rankine cycle, Brayton cycle, Diesel cycle, Otto cycle (introduction to Internal Combustion Engines), Heat transfer of electrical and electronic devices. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechatronics Engineering and Automation |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP112s | Thermal Power Engineering | 3 CH | |||||||||
Prerequisites | ( PHM041s ) AND ( PHM022s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Thermal System, Control Volume, States of the Working Medium, Processes and Cycles, Calculation of Work, Heat Exchange with the Surroundings, Ideal Gases, Equation of State, Pure Substances, Phase Equilibrium, Tables of Thermodynamic Properties, First Law of Thermodynamics on Steady State Steady Flow Open Systems, and Applications such as simple Steam Rankine cycle, Brayton cycle, Diesel cycle, Otto cycle (introduction to Internal Combustion Engines), Heat transfer of electrical and electronic devices. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Electrical Engineering |
2 | ||||||||||
Electrical Power and Machines Engineering |
4 | ||||||||||
Electronics and Communications Engineering |
4 | ||||||||||
Computer and Systems Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 0% | 50% |
MEP211 | Thermodynamics | 4 CH | |||||||||
Prerequisites | ( MEP111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Heat Engines, Refrigerator and Heat Pump, Second Law of Thermodynamics, Kelvin Plank Statement, Clausius Statement, Clausius Inequality, Entropy, Irreversibility, Reversible Process, Entropy Change of a Reversible Process, Entropy Change of Solids and Liquids, Entropy Change of Ideal Gases, Gibbs Relations, Isentropic Process, Entropy Increase Principle, Exergy and Availability, Reversible Work, Exergy Destruction Principle, The Second Law Efficiency, Air Standard Cycles, Vapor Cycles, Property Diagrams. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
1 | 4 | |||||||||
Energy and Renewable Energy Engineering |
1 | 4 | |||||||||
Materials Engineering |
1 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP211s | Thermodynamics | 4 CH | |||||||||
Prerequisites | ( MEP111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Heat Engines, Refrigerator and Heat Pump, Second Law of Thermodynamics, Kelvin Plank Statement, Clausius Statement, Clausius Inequality, Entropy, Irreversibility, Reversible Process, Entropy Change of a Reversible Process, Entropy Change of Solids and Liquids, Entropy Change of Ideal Gases, Gibbs Relations, Isentropic Process, Entropy Increase Principle, Exergy and Availability, Reversible Work, Exergy Destruction Principle, The Second Law Efficiency, Air Standard Cycles, Vapor Cycles, Property Diagrams. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
1 | ||||||||||
Design and Production Engineering |
4 | ||||||||||
Mechanical Power Engineering |
4 | ||||||||||
Automotive Engineering |
4 | ||||||||||
Mechatronics Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |
MEP212 | Heat Transfer | 4 CH | |||||||||
Prerequisites | ( MEP211 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 3 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Thermal Conduction: The General Equation, Steady One Dimensional Conduction, Conduction without Heat Generation, Plane Wall, Composite Plane Wall, Composite Plane Wall Subjected to Convection, Overall Heat Transfer Coefficient, Cylindrical Shell, Composite Cylindrical Wall Subjected to Convection, Spherical Shell, Composite Spherical Shell Subjected to Convection, Extended Surfaces (Fins), Conduction with Uniform Internal Heat Generation, Conduction with Variable Thermal Conductivity, Steady Two Dimensional Conduction, Unsteady One Dimensional Conduction (Transient Conduction), Periodic Conduction. Convection: Types of Convection, Dimensionless Groups, Dimensional Analyses, Buckingham’s Pi Theory, Dimensionless Groups in Convection, Natural Convection, Forced Convection. Heat Exchanger: Heat Exchanger Types, Logarithmic Mean Temperature Difference, Effectiveness of Heat Exchangers. Thermal Radiation: Basic Concepts, Stefan-Boltzmann Law, Planck’s Law, Radiation Properties of Real Surfaces, Emissivity and Absorptivity, Kirchhoff’s Law, Emissivity of Real Surfaces, Gray Surfaces, Selective Surfaces, Heat Exchange by Radiation, Heat Exchange between Two Planes, Heat Exchange between Two Cylinders or Spheres, Heat Exchange between Gray Surfaces, View Factors. Mass Transfer, Fick’s Law of Diffusion, Mass Transfer Rate from a Pool of Liquid, and from a Liquid Droplet. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
2 | 5 | |||||||||
Materials Engineering |
2 | 5 | |||||||||
Energy and Renewable Energy Engineering |
1 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP212s | Heat Transfer | 4 CH | |||||||||
Prerequisites | ( MEP211s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 3 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Thermal Conduction: The General Equation, Steady One Dimensional Conduction, Conduction without Heat Generation, Plane Wall, Composite Plane Wall, Composite Plane Wall Subjected to Convection, Overall Heat Transfer Coefficient, Cylindrical Shell, Composite Cylindrical Wall Subjected to Convection, Spherical Shell, Composite Spherical Shell Subjected to Convection, Extended Surfaces (Fins), Conduction with Uniform Internal Heat Generation, Conduction with Variable Thermal Conductivity, Steady Two Dimensional Conduction, Unsteady One Dimensional Conduction (Transient Conduction), Periodic Conduction. Convection: Types of Convection, Dimensionless Groups, Dimensional Analyses, Buckingham’s Pi Theory, Dimensionless Groups in Convection, Natural Convection, Forced Convection. Heat Exchanger: Heat Exchanger Types, Logarithmic Mean Temperature Difference, Effectiveness of Heat Exchangers. Thermal Radiation: Basic Concepts, Stefan-Boltzmann Law, Planck’s Law, Radiation Properties of Real Surfaces, Emissivity and Absorptivity, Kirchhoff’s Law, Emissivity of Real Surfaces, Gray Surfaces, Selective Surfaces, Heat Exchange by Radiation, Heat Exchange between Two Planes, Heat Exchange between Two Cylinders or Spheres, Heat Exchange between Gray Surfaces, View Factors. Mass Transfer, Fick’s Law of Diffusion, Mass Transfer Rate from a Pool of Liquid, and from a Liquid Droplet. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
2 | ||||||||||
Design and Production Engineering |
6 | ||||||||||
Mechanical Power Engineering |
6 | ||||||||||
Automotive Engineering |
6 | ||||||||||
Mechatronics Engineering |
9 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP213 | Thermal Analysis of Buildings | 3 CH | |||||||||
Prerequisites | ( PHM012 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Integration of fundamentals of thermodynamics (Basic concepts and definitions, System and control volume, Property and state, Processes and cycles, Ideal gases, State equation, Specific heat at constant pressure and volume, First law of thermodynamics, Internal energy and enthalpy). Integration of fundamentals of heat transfer (One and multi،dimensional steady and unsteady conduction heat transfer, Free and forced convection, Radiation heat transfer as applied to building materials and geometries). | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Building Engineering |
2 | 5 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP213s | Thermal Analysis of Buildings | 3 CH | |||||||||
Prerequisites | ( PHM012s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Integration of fundamentals of thermodynamics (Basic concepts and definitions, System and control volume, Property and state, Processes and cycles, Ideal gases, State equation, Specific heat at constant pressure and volume, First law of thermodynamics, Internal energy and enthalpy). Integration of fundamentals of heat transfer (One and multi،dimensional steady and unsteady conduction heat transfer, Free and forced convection, Radiation heat transfer as applied to building materials and geometries). | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP311 | Combustion | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Fuel Bonding Energies, Chemical Structure Change due to Oxidation, Fuel Heating Values, Adiabatic and Non-Adiabatic Combustion Temperatures, Concentrations of Combustion Products under Chemical Equilibrium Conditions, Rates of Chemical Reactions, Stabilization of Premixed Flames, Laminar Flame Speed, Turbulent Flame Speed, Flame Stabilization at Higher Flow rates, Reaction Zones in Non-Premixed Flames, Diffusion Flame Length, Diffusion Flame Blowout Limits, Combustion Efficiency and Flame Generated Pollution, Liquid Fuel Sprays, Atomizers, Time of Fuel Droplet Evaporation, Physical and Chemical Ignition Delays, Combustion of Solid Fuels on Grates, Pulverized Coal Combustion, Proximate and Ultimate Analysis of Coal, Detonation and Explosives. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
3 | 7 | |||||||||
Energy and Renewable Energy Engineering |
1 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP311s | Combustion | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Fuel Bonding Energies, Chemical Structure Change due to Oxidation, Fuel Heating Values, Adiabatic and Non-Adiabatic Combustion Temperatures, Concentrations of Combustion Products under Chemical Equilibrium Conditions, Rates of Chemical Reactions, Stabilization of Premixed Flames, Laminar Flame Speed, Turbulent Flame Speed, Flame Stabilization at Higher Flow rates, Reaction Zones in Non-Premixed Flames, Diffusion Flame Length, Diffusion Flame Blowout Limits, Combustion Efficiency and Flame Generated Pollution, Liquid Fuel Sprays, Atomizers, Time of Fuel Droplet Evaporation, Physical and Chemical Ignition Delays, Combustion of Solid Fuels on Grates, Pulverized Coal Combustion, Proximate and Ultimate Analysis of Coal, Detonation and Explosives. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP312 | Fundamentals of Internal Combustion Engines | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Classification of Internal Combustion Engines. The Fuel-Air Standard Cycle, Indicated Cycle Deviations between the Indicated Cycle and Fuel-Air Standard Cycle, Combustion Chambers, Fuel Properties and its Impact on Engine Performance. Combustion in Diesel Engines and Gasoline Engines, Detonation and Diesel Knock. Friction and Lubrication, Effect of Engine Operating Conditions on Friction Loss, Engine Performance at Constant Speed, Effect of Engine Speed on Friction Loss, Engine Performance at Variable Speeds and Constant Load, Properties and Classification of Engine Lubricating Oil, Testing of the Lubricating Oil, Oil Filters for the Engines, Cooling Loss, Effect of Engine Operating Conditions on Cooling Loss, Factors Affecting the Cooling of the Engine Surfaces, Temperatures Limit for the Engine Cooling Surfaces, Engine Cooling Systems, The Engine Actual Thermal Cycle. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
4 | ||||||||||
Energy and Renewable Energy Engineering |
5 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP312s | Fundamentals of Internal Combustion Engines | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Classification of Internal Combustion Engines. The Fuel-Air Standard Cycle, Indicated Cycle Deviations between the Indicated Cycle and Fuel-Air Standard Cycle, Combustion Chambers, Fuel Properties and its Impact on Engine Performance. Combustion in Diesel Engines and Gasoline Engines, Detonation and Diesel Knock. Friction and Lubrication, Effect of Engine Operating Conditions on Friction Loss, Engine Performance at Constant Speed, Effect of Engine Speed on Friction Loss, Engine Performance at Variable Speeds and Constant Load, Properties and Classification of Engine Lubricating Oil, Testing of the Lubricating Oil, Oil Filters for the Engines, Cooling Loss, Effect of Engine Operating Conditions on Cooling Loss, Factors Affecting the Cooling of the Engine Surfaces, Temperatures Limit for the Engine Cooling Surfaces, Engine Cooling Systems, The Engine Actual Thermal Cycle. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP313 | Thermal Power Plants | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Rankine Cycle Processes and Calculations, Methods of Improvement in Rankine Cycle Thermal Efficiency, Superheat, Reheat, Regenerative Rankine Cycles, Regeneration with an Open Type Feed Water Heater, Regeneration with a Closed Type Feed Water Heater, Fire Tube Boilers, Construction and Operation, Water Tube Boilers, Superheaters, Economizers, Air Heaters, Steam Generator Losses and Efficiency, Work of Turbines, Impulse Turbines, Reaction Turbines, Effect of Dryness Fraction on the Turbine Efficiency and Turbine Life-Time, Types of Condensers, De-aerators, Ejectors, Construction of Feed Water Heaters, Steam Pipes and Steam Traps, Cooling Towers, Natural Draft and Forced Draft, Water Pumps. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP313s | Thermal Power Plants | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Rankine Cycle Processes and Calculations, Methods of Improvement in Rankine Cycle Thermal Efficiency, Superheat, Reheat, Regenerative Rankine Cycles, Regeneration with an Open Type Feed Water Heater, Regeneration with a Closed Type Feed Water Heater, Fire Tube Boilers, Construction and Operation, Water Tube Boilers, Superheaters, Economizers, Air Heaters, Steam Generator Losses and Efficiency, Work of Turbines, Impulse Turbines, Reaction Turbines, Effect of Dryness Fraction on the Turbine Efficiency and Turbine Life-Time, Types of Condensers, De-aerators, Ejectors, Construction of Feed Water Heaters, Steam Pipes and Steam Traps, Cooling Towers, Natural Draft and Forced Draft, Water Pumps. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP314 | Power Plant Technology | 4 CH | |||||||||
Prerequisites | ( MEP313 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Co-Generation Plants, Combined Cycles, Heat Recovery Boilers, Efficiency of Combined Cycles, Performance Characteristics of Power Stations, Heat Rate and Incremental Rate, Optimum Load Division Among Power Generation Units, Control of the Steam Generators, Convection and Radiant Type Superheaters, Governing of Steam Turbines, Steam Partial Admission and Full Admission, Load Frequency Characteristics, Speed Regulation, Parallel Operation, Lubrication Systems, Protection and Tripping Systems, Start-Up and Shut Down Procedures, Procedure of Meeting the Power Demands: Adding Peaking Load Units, Connection between Zones of Different Longitudes, Energy Storage, Introduction to Nuclear Energy Power Plants, Economical Consideration of Thermal Power Plants. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP314s | Power Plant Technology | 4 CH | |||||||||
Prerequisites | ( MEP313s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Co-Generation Plants, Combined Cycles, Heat Recovery Boilers, Efficiency of Combined Cycles, Performance Characteristics of Power Stations, Heat Rate and Incremental Rate, Optimum Load Division Among Power Generation Units, Control of the Steam Generators, Convection and Radiant Type Superheaters, Governing of Steam Turbines, Steam Partial Admission and Full Admission, Load Frequency Characteristics, Speed Regulation, Parallel Operation, Lubrication Systems, Protection and Tripping Systems, Start-Up and Shut Down Procedures, Procedure of Meeting the Power Demands: Adding Peaking Load Units, Connection between Zones of Different Longitudes, Energy Storage, Introduction to Nuclear Energy Power Plants, Economical Consideration of Thermal Power Plants. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP411 | Control Systems of Internal Combustion Engines | 3 CH | |||||||||
Prerequisites | ( MEP312 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
The Performance Map of 4-Stroke and 2-Stroke Engines. Knock Resistance, Supercharging: Methods, Turbocharging Control, Matching of the Engine and Supercharger. Ignition: Types and Components, Conventional and Electronic Ignition. Spark Timing Control, Governors: Types, Components and Testing. Sources of Pollutant Emissions from Internal Combustion Engines to the Atmosphere and the Methods of Emissions Control. Engine Management Systems, Engine Control Functional Subsystems, Gas-Phase Flow Control (Air System), Liquid-Phase Flow Control (Fuel System), Torque Control, Engine Speed Control, Engine Protection. Mixture Preparation in Spark Ignition Engines and Compression Ignition Engines. Fuel Injection Systems in Diesel Engines. Diesel Engine Characteristics and Analysis. Modern Injection Systems with High Injection Pressures, Common Rail and HEUI, and the Utilization of Sophisticated Electronic Control Methods. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP411s | Control Systems of Internal Combustion Engines | 3 CH | |||||||||
Prerequisites | ( MEP312s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
The Performance Map of 4-Stroke and 2-Stroke Engines. Knock Resistance, Supercharging: Methods, Turbocharging Control, Matching of the Engine and Supercharger. Ignition: Types and Components, Conventional and Electronic Ignition. Spark Timing Control, Governors: Types, Components and Testing. Sources of Pollutant Emissions from Internal Combustion Engines to the Atmosphere and the Methods of Emissions Control. Engine Management Systems, Engine Control Functional Subsystems, Gas-Phase Flow Control (Air System), Liquid-Phase Flow Control (Fuel System), Torque Control, Engine Speed Control, Engine Protection. Mixture Preparation in Spark Ignition Engines and Compression Ignition Engines. Fuel Injection Systems in Diesel Engines. Diesel Engine Characteristics and Analysis. Modern Injection Systems with High Injection Pressures, Common Rail and HEUI, and the Utilization of Sophisticated Electronic Control Methods. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP412 | Heat Engines | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Thermodynamic Cycles and Heat Engines, Stirling Engine as an Example of a Heat Engine, Ideal Stirling Cycle, Actual Stirling Cycle, Deviation between the Ideal and Actual Cycles. Arrangements of Stirling Engines, Drive Mechanisms, Working Fluids in Stirling Engines, Heaters – Types, Methods of External Heating. Coolers, Regenerators, Advantages and Disadvantages of Stirling Engines, Applications of Stirling Engines. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP412s | Heat Engines | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Thermodynamic Cycles and Heat Engines, Stirling Engine as an Example of a Heat Engine, Ideal Stirling Cycle, Actual Stirling Cycle, Deviation between the Ideal and Actual Cycles. Arrangements of Stirling Engines, Drive Mechanisms, Working Fluids in Stirling Engines, Heaters – Types, Methods of External Heating. Coolers, Regenerators, Advantages and Disadvantages of Stirling Engines, Applications of Stirling Engines. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
5 | 1 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP413 | Gas Fueled Engines | 3 CH | |||||||||
Prerequisites | ( MEP312 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Alternative Fuels for Internal Combustion Engines, Availability and Suitability to Piston Engines. Concept of Conventional Fuels. Potential Alternative Fuels. Ethanol. Methanol. DEE / DME, Hydrogen, Liquified Petroleum Gas. Natural Gas. Producer Gas and Vegetable Oils Use in Internal Combustion Engines. Merits and Demerits of Various Fuels. Alcohol Fuels Properties as Engine Fuels, Flexible Fuel Vehicle, Emulsions, Dual Fuel Systems, Spark Assisted Diesel Engines, Surface Ignition Engines, Ignition Accelerators, Manufacturing of Alcohol Fuels. Gaseous Fuels, Hydrogen, Properties, Use in Compression Ignition Engines, Use in Spark Ignition Engines, Storage Methods, Safety Precautions, Production Methods. Producer Gas and Biogas, Raw Materials, Gasification, Properties, Cleaning up, the Gas Use in Spark Ignition Engines and Dual Fuel Engines. Liquified Petroleum Gas and CNG, Properties, Use in Spark Ignition and Compression Ignition Engines. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP413s | Gas Fueled Engines | 3 CH | |||||||||
Prerequisites | ( MEP312s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Alternative Fuels for Internal Combustion Engines, Availability and Suitability to Piston Engines. Concept of Conventional Fuels. Potential Alternative Fuels. Ethanol. Methanol. DEE / DME, Hydrogen, Liquified Petroleum Gas. Natural Gas. Producer Gas and Vegetable Oils Use in Internal Combustion Engines. Merits and Demerits of Various Fuels. Alcohol Fuels Properties as Engine Fuels, Flexible Fuel Vehicle, Emulsions, Dual Fuel Systems, Spark Assisted Diesel Engines, Surface Ignition Engines, Ignition Accelerators, Manufacturing of Alcohol Fuels. Gaseous Fuels, Hydrogen, Properties, Use in Compression Ignition Engines, Use in Spark Ignition Engines, Storage Methods, Safety Precautions, Production Methods. Producer Gas and Biogas, Raw Materials, Gasification, Properties, Cleaning up, the Gas Use in Spark Ignition Engines and Dual Fuel Engines. Liquified Petroleum Gas and CNG, Properties, Use in Spark Ignition and Compression Ignition Engines. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP414 | Biomass and Waste Conversion Technology | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP311 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Characterization of Waste, Types of Biomass, Biomass Properties, Pre-Treatment of Biomass, Thermo-Chemical Processes, Fast and Slow Pyrolysis, Gasification, Transesterification, Design of Gasifiers, Drying and Devolatilization, Heat and Mass Transfer across Small and Large Biomass Particles, Combustion, Chemical Kinetics, Types of Reactors, Incinerators, Bio-Chemical Conversion, Anaerobic Digestion and Fermentation, Operation of Biomass Boilers and Stoves, Use of Bio-Fuels in Internal Combustion Engines and Gas Turbines, Emissions, Cost Considerations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP414s | Biomass and Waste Conversion Technology | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP311s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Characterization of Waste, Types of Biomass, Biomass Properties, Pre-Treatment of Biomass, Thermo-Chemical Processes, Fast and Slow Pyrolysis, Gasification, Transesterification, Design of Gasifiers, Drying and Devolatilization, Heat and Mass Transfer across Small and Large Biomass Particles, Combustion, Chemical Kinetics, Types of Reactors, Incinerators, Bio-Chemical Conversion, Anaerobic Digestion and Fermentation, Operation of Biomass Boilers and Stoves, Use of Bio-Fuels in Internal Combustion Engines and Gas Turbines, Emissions, Cost Considerations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP221 | Fluid Mechanics and Turbo-Machinery | 4 CH | |||||||||
Prerequisites | ( PHM113 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Properties of Fluids, Density, Pressure, Pressure Measurement, Forces on Submerged Bodies, Viscosity, Viscous Boundary Layers, Continuum Hypothesis, Streamlines, Velocity and Acceleration, Continuity Equation, Classification of Flow Fields: Pipe Flow, Jet Flow, Wake Flow, Boundary Layer Flow, Flow in Closed Conduits, Bernoulli’s Equation, Major and Minor Losses in Pipes, Laminar and Turbulent Flows, Similitude and Dimensional Analysis, Lagrangian and Eulerian Coordinates, Transport Theorem on a Control Volume, Navier-Stokes Equation, Flow around Immersed Bodies, Drag and Lift Forces, Compressible Flow, Stagnation Properties, Mach Number and Sonic Velocity, Equations of Gas Dynamics, Flow through Nozzles, Shock Waves, Classification of Turbomachines, Operation of Pumps, Series and Parallel Operation, Selection of Pumps. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
1 | 4 | |||||||||
Energy and Renewable Energy Engineering |
2 | 5 | |||||||||
Energy and Renewable Energy Engineering |
1 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP221s | Fluid Mechanics and Turbo-Machinery | 4 CH | |||||||||
Prerequisites | ( PHM112s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Properties of Fluids, Density, Pressure, Pressure Measurement, Forces on Submerged Bodies, Viscosity, Viscous Boundary Layers, Continuum Hypothesis, Streamlines, Velocity and Acceleration, Continuity Equation, Classification of Flow Fields: Pipe Flow, Jet Flow, Wake Flow, Boundary Layer Flow, Flow in Closed Conduits, Bernoulli’s Equation, Major and Minor Losses in Pipes, Laminar and Turbulent Flows, Similitude and Dimensional Analysis, Lagrangian and Eulerian Coordinates, Transport Theorem on a Control Volume, Navier-Stokes Equation, Flow around Immersed Bodies, Drag and Lift Forces, Compressible Flow, Stagnation Properties, Mach Number and Sonic Velocity, Equations of Gas Dynamics, Flow through Nozzles, Shock Waves, Classification of Turbomachines, Operation of Pumps, Series and Parallel Operation, Selection of Pumps. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
2 | ||||||||||
Design and Production Engineering |
5 | ||||||||||
Mechanical Power Engineering |
5 | ||||||||||
Automotive Engineering |
5 | ||||||||||
Mechatronics Engineering |
6 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP222 | Introduction to Fluid Mechanics | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Properties of Fluids, Density, Pressure, Pressure Measurement, Forces on Submerged Bodies, Viscosity, Viscous Boundary Layers, Continuum Hypothesis, Streamlines, Velocity and Acceleration, Continuity Equation, Classification of Flow Fields: Pipe Flow, Jet Flow, Wake Flow, Boundary Layer Flow, Flow in Closed Conduits, Bernoulli’s Equation, Major and Minor Losses in Pipes, Laminar and Turbulent Flows, Similitude and Dimensional Analysis, Lagrangian and Eulerian Coordinates, Transport Theorem on a Control Volume, Navier Stokes Equation. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechatronics Engineering and Automation |
2 | 5 | |||||||||
Materials Engineering |
1 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP222s | Introduction to Fluid Mechanics | 3 CH | |||||||||
Prerequisites | ( MEP111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Properties of Fluids, Density, Pressure, Pressure Measurement, Forces on Submerged Bodies, Viscosity, Viscous Boundary Layers, Continuum Hypothesis, Streamlines, Velocity and Acceleration, Continuity Equation, Classification of Flow Fields: Pipe Flow, Jet Flow, Wake Flow, Boundary Layer Flow, Flow in Closed Conduits, Bernoulli’s Equation, Major and Minor Losses in Pipes, Laminar and Turbulent Flows, Similitude and Dimensional Analysis, Lagrangian and Eulerian Coordinates, Transport Theorem on a Control Volume, Navier Stokes Equation. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP321 | Incompressible Flow Machines | 3 CH | |||||||||
Prerequisites | ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Centrifugal Pumps: Theory, Application, Construction, Components, Performance Curves, Efficiencies, Operation, Pumps in Series, Pumps in Parallel, Cavitation Phenomenon, Radial and axial Thrust, Pump Selection, Maintenance and Trouble Shooting. Axial-Flow Pumps: Theory, Application, Construction, Components, Performance Curves. Positive Displacement Pumps: Theory, Classification, Application, Construction, Components, Performance Curves. Water Turbines: Theory, Impulse Turbines, Reaction Turbines, Application, Construction, Components, Cavitation, Energy Calculation and Performance. Hydro-Electric Power Plants. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP321s | Incompressible Flow Machines | 3 CH | |||||||||
Prerequisites | ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Centrifugal Pumps: Theory, Application, Construction, Components, Performance Curves, Efficiencies, Operation, Pumps in Series, Pumps in Parallel, Cavitation Phenomenon, Radial and axial Thrust, Pump Selection, Maintenance and Trouble Shooting. Axial-Flow Pumps: Theory, Application, Construction, Components, Performance Curves. Positive Displacement Pumps: Theory, Classification, Application, Construction, Components, Performance Curves. Water Turbines: Theory, Impulse Turbines, Reaction Turbines, Application, Construction, Components, Cavitation, Energy Calculation and Performance. Hydro-Electric Power Plants. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP322 | Compressible Flow Machines | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Centrifugal Fans, Blowers and Compressors: Theory, Classification, Construction, Application, Performance and Energy Calculation. Airfoil Theory. Axial-Flow Fans and Compressors: Theory, Components Application, Performance and Energy Calculation. Reciprocating compressors: Theory, Components, Application, Performance and Energy Calculation. Steam Turbines: Theory, Types, Components, Application and Energy Calculation. Gas Turbines: Theory, Types, Components, Application and Energy Calculation. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
3 | 1 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP322s | Compressible Flow Machines | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Centrifugal Fans, Blowers and Compressors: Theory, Classification, Construction, Application, Performance and Energy Calculation. Airfoil Theory. Axial-Flow Fans and Compressors: Theory, Components Application, Performance and Energy Calculation. Reciprocating compressors: Theory, Components, Application, Performance and Energy Calculation. Steam Turbines: Theory, Types, Components, Application and Energy Calculation. Gas Turbines: Theory, Types, Components, Application and Energy Calculation. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP421 | Sustainable Energy | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Assessment of Current and Potential Future Energy Systems, Covering Resources, Extraction, Conversion, and End-Use Technologies, with Emphasis on Meeting Regional and Global Energy Needs in the 21st Century in a Sustainable Manner. The Course will Examine Various Renewable and Conventional Energy Production Technologies, Energy End-Use Practices and Alternatives, and Consumption Practices in Different Countries. Students will Learn a Quantitative Framework to Aid in Evaluation and Analysis of Energy Technology System Proposals in the Context of Engineering, Social, Economic, and Environmental Goals. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP421s | Sustainable Energy | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Assessment of Current and Potential Future Energy Systems, Covering Resources, Extraction, Conversion, and End-Use Technologies, with Emphasis on Meeting Regional and Global Energy Needs in the 21st Century in a Sustainable Manner. The Course will Examine Various Renewable and Conventional Energy Production Technologies, Energy End-Use Practices and Alternatives, and Consumption Practices in Different Countries. Students will Learn a Quantitative Framework to Aid in Evaluation and Analysis of Energy Technology System Proposals in the Context of Engineering, Social, Economic, and Environmental Goals. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP422 | Energy Storage Technology | 3 CH | |||||||||
Prerequisites | ( MEP313 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Energy Storage, Power versus Energy, Electrochemical Energy Storage; Types of Batteries, Methods of Charging and Discharging of Batteries, Mobile and Fixed Energy Storage. Types of Mechanical Energy Storage; Pumped Hydro, Compressed Gas, Flywheel, Thermal and Phase Change Materials. Applications of Energy Storage Technology in the of Power Generation and in the Field of Refrigeration and Air Conditioning. Introduction to Modelling of Several Types of Energy Storage Systems. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP422s | Energy Storage Technology | 3 CH | |||||||||
Prerequisites | ( MEP313s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Energy Storage, Power versus Energy, Electrochemical Energy Storage; Types of Batteries, Methods of Charging and Discharging of Batteries, Mobile and Fixed Energy Storage. Types of Mechanical Energy Storage; Pumped Hydro, Compressed Gas, Flywheel, Thermal and Phase Change Materials. Applications of Energy Storage Technology in the of Power Generation and in the Field of Refrigeration and Air Conditioning. Introduction to Modelling of Several Types of Energy Storage Systems. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP423 | Hydro-Tidal and Wave Energies | 3 CH | |||||||||
Prerequisites | ( MEP321 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Water Renewable Energy Resources, Tidal Energy Principles, Analysis of Tidal Energy Resources and its Relation to Wind, Classification of Tidal Energy Resources, Egypt Tidal Energy, Tidal Energy Utilization, Installation of Turbines for Tidal Energy, Turbines Performance Analysis with Tidal Energy, Energy Storage Techniques with Tidal Energy, Wave Energy Principles, Utilization of Wave Energy, Wave Energy Classification, Wave Energy Turbines, Water and Air Columns, Operation of Wave Energy Turbines, Performance Analysis for Wave Energy Turbines, Characteristics of Used Turbines, Column Separation, Energy Storage Techniques, Wave Energy Utilization in Egypt, Case Studies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP423s | Hydro-Tidal and Wave Energies | 3 CH | |||||||||
Prerequisites | ( MEP321s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Water Renewable Energy Resources, Tidal Energy Principles, Analysis of Tidal Energy Resources and its Relation to Wind, Classification of Tidal Energy Resources, Egypt Tidal Energy, Tidal Energy Utilization, Installation of Turbines for Tidal Energy, Turbines Performance Analysis with Tidal Energy, Energy Storage Techniques with Tidal Energy, Wave Energy Principles, Utilization of Wave Energy, Wave Energy Classification, Wave Energy Turbines, Water and Air Columns, Operation of Wave Energy Turbines, Performance Analysis for Wave Energy Turbines, Characteristics of Used Turbines, Column Separation, Energy Storage Techniques, Wave Energy Utilization in Egypt, Case Studies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP424 | Water Distribution Networks | 3 CH | |||||||||
Prerequisites | ( MEP321 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Steady Incompressible Flow Through Pipe Systems, Pipe Flow: Darcy-Weisbach Equation, Moody Diagram, Simple Pipe Problems, Minor Losses, Equivalent Length of Minor Losses, The Siphon Pipes Connections: Pipes In Series, Pipes In Parallel, Graphical Solution, Branching of Pipes, Pumping from One Reservoir to Two Or More Reservoirs, Hazen-Williams Formula, Network of Pipes: Hardy Cross Method, Using Hazen-Williams Formula, Using Friction Factor of Moody Chart, Linear Theory Method, Systems with Multiple Fixed-Pressure-Head Elevations, Pseudo Loops, Hydraulic Path, Graphical Solutions of Branch-Line Pumping Systems: Branches in Closed Loop Systems, Branches In Open-Ended Loop Systems. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP424s | Water Distribution Networks | 3 CH | |||||||||
Prerequisites | ( MEP321s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Steady Incompressible Flow Through Pipe Systems, Pipe Flow: Darcy-Weisbach Equation, Moody Diagram, Simple Pipe Problems, Minor Losses, Equivalent Length of Minor Losses, The Siphon Pipes Connections: Pipes In Series, Pipes In Parallel, Graphical Solution, Branching of Pipes, Pumping from One Reservoir to Two Or More Reservoirs, Hazen-Williams Formula, Network of Pipes: Hardy Cross Method, Using Hazen-Williams Formula, Using Friction Factor of Moody Chart, Linear Theory Method, Systems with Multiple Fixed-Pressure-Head Elevations, Pseudo Loops, Hydraulic Path, Graphical Solutions of Branch-Line Pumping Systems: Branches in Closed Loop Systems, Branches In Open-Ended Loop Systems. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP425 | Aircraft Propulsion | 3 CH | |||||||||
Prerequisites | ( MEP311 ) AND ( MEP322 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Air/Gas Flow Across Propulsion Systems, Equation of Thrust, Turbo-Propulsion Aircrafts, Turbo-Jet Propulsion in Jet Engines, Turbo-Fan Engines, By Pass Ratio, Specific Fuel Consumption, Propulsive Efficiency, Overall Efficiency, Air Flow Across Aircraft Wings, Intake, Inlet Stagnation Properties, Compressor, Turbine, Combustion Chamber, After-Burner, Combustion Stability Limits, Pressure Loss, Flow Through the Nozzle, Variable Area Nozzles, Dimensional Analysis for Matching of the Gas Turbine Engine Components, Force Balance, Take-Off, Climbing, Cruising, Landing, Manoeuvre. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP425s | Aircraft Propulsion | 3 CH | |||||||||
Prerequisites | ( MEP311s ) AND ( MEP322s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Air/Gas Flow Across Propulsion Systems, Equation of Thrust, Turbo-Propulsion Aircrafts, Turbo-Jet Propulsion in Jet Engines, Turbo-Fan Engines, By Pass Ratio, Specific Fuel Consumption, Propulsive Efficiency, Overall Efficiency, Air Flow Across Aircraft Wings, Intake, Inlet Stagnation Properties, Compressor, Turbine, Combustion Chamber, After-Burner, Combustion Stability Limits, Pressure Loss, Flow Through the Nozzle, Variable Area Nozzles, Dimensional Analysis for Matching of the Gas Turbine Engine Components, Force Balance, Take-Off, Climbing, Cruising, Landing, Manoeuvre. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP426 | Solar Energy | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Intensity of Solar Radiation within the Outer Space, Calculation of the Solar Intensity on the Earth, Availability and Usability of Solar Energy, Measurement of the Solar Intensity, Direct and Diffuse Radiation, Reflection from the Ground, Solar Angles, Shades, the Equation of Time, Incidence Angle on Horizontal and Inclined Surfaces, Theory of the Flat Plate Collector, Transmission through Glass, Heat Loss Calculations, Collector Performance, Solar Energy Concentrators, Point and Line Concentrators, Cylindrical Trough, Parabolic Trough, Parabolic Dish, Central Receiver, Heliostat, Heliostat Optimum Placement, Sun Beam Tracking, Shadowing and Blocking, Concentration Ratios, Fresnel Lens, Thermal performance, Heat Transfer Coefficients, Receiver Efficiency. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP426s | Solar Energy | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Intensity of Solar Radiation within the Outer Space, Calculation of the Solar Intensity on the Earth, Availability and Usability of Solar Energy, Measurement of the Solar Intensity, Direct and Diffuse Radiation, Reflection from the Ground, Solar Angles, Shades, the Equation of Time, Incidence Angle on Horizontal and Inclined Surfaces, Theory of the Flat Plate Collector, Transmission through Glass, Heat Loss Calculations, Collector Performance, Solar Energy Concentrators, Point and Line Concentrators, Cylindrical Trough, Parabolic Trough, Parabolic Dish, Central Receiver, Heliostat, Heliostat Optimum Placement, Sun Beam Tracking, Shadowing and Blocking, Concentration Ratios, Fresnel Lens, Thermal performance, Heat Transfer Coefficients, Receiver Efficiency. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
5 | 3 | |||||||||
Mechanical Power Engineering |
5 | 3 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP427 | Wind Energy | 3 CH | |||||||||
Prerequisites | ( MEP322 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Wind Energy, Wind Speed Classification, Wind Data and Wind Rose, Statistical Analysis of Wind Data, Types of Wind Turbines, Instrumentations Used for Operating Wind Data, Construction Details of a Wind Turbine, Wind Turbine Control Schemes, Estimation of Wind Power, Betz’ Theorem, Blade Element Theory, Translating Wind Power Machines, Vertical-Axis Wind-Turbines – Savonius and Darriews, Airfoil Theory, Horizontal-Axis Wind Turbines, Wind Energy for Water Pumping. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP427s | Wind Energy | 3 CH | |||||||||
Prerequisites | ( MEP322s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Wind Energy, Wind Speed Classification, Wind Data and Wind Rose, Statistical Analysis of Wind Data, Types of Wind Turbines, Instrumentations Used for Operating Wind Data, Construction Details of a Wind Turbine, Wind Turbine Control Schemes, Estimation of Wind Power, Betz’ Theorem, Blade Element Theory, Translating Wind Power Machines, Vertical-Axis Wind-Turbines – Savonius and Darriews, Airfoil Theory, Horizontal-Axis Wind Turbines, Wind Energy for Water Pumping. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP428 | Hydraulic Transmission | 3 CH | |||||||||
Prerequisites | ( MEP221 ) AND ( MEP321 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Hydrostatic Power Systems: Theory, Application, Components, Energy Calculation, Energy Storage. Hydrodynamic Power Transmission Systems: Theory, Application, Components, Energy Calculation. Hydraulic Power Generator (Pump): Types, Components, Calculations. Hydraulic Motor (Actuator): Types, Components, Calculations. Hydraulic Accumulators: Dead Weight Loaded Accumulators, Air-Loaded (Pneumatic) and Spring-Loaded Accumulators. Control and Regulation Devices: Different Types of Valves and Alarms. Hydraulic Coupling: Theory, Application, Components, Performance and Control. Hydraulic Torque Converter: Theory, Application, Components, Performance and Control. Hydraulic Servomotors: Theory, Application, Components. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP428s | Hydraulic Transmission | 3 CH | |||||||||
Prerequisites | ( MEP221s ) AND ( MEP321s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Hydrostatic Power Systems: Theory, Application, Components, Energy Calculation, Energy Storage. Hydrodynamic Power Transmission Systems: Theory, Application, Components, Energy Calculation. Hydraulic Power Generator (Pump): Types, Components, Calculations. Hydraulic Motor (Actuator): Types, Components, Calculations. Hydraulic Accumulators: Dead Weight Loaded Accumulators, Air-Loaded (Pneumatic) and Spring-Loaded Accumulators. Control and Regulation Devices: Different Types of Valves and Alarms. Hydraulic Coupling: Theory, Application, Components, Performance and Control. Hydraulic Torque Converter: Theory, Application, Components, Performance and Control. Hydraulic Servomotors: Theory, Application, Components. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP231 | Measurement and Instrumentation | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 3 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Characteristics of Sensors, Flow rate Measurement Principles, Orifice-Meter, Venturi-Meter, Coriolis Flow Meter, Turbine Flow Meter, Rotameter, Velocity Measurements, Pitot Tube, Vane Anemometer, Hot Wire Anemometer, Laser Doppler Anemometer, Particle Image Velocimetry, Pressure Measurement, Manometer, Bourdon Tube Gauge, Piezoelectric Sensor, Temperature Measurement, Thermometer, Thermocouple, Thermistor, Optical Pyrometer, Rotational Speed Meters, Tachometer, Torque Measurement, Strain Gauges, Gas Analysis, Electro-Chemical Gas Analyzer, Accuracy, Precision, Statistical Methods Error Analysis and Uncertainty. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
3 | 1 | |||||||||
Manufacturing Engineering |
3 | 1 | |||||||||
Materials Engineering |
3 | 1 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP231s | Measurement and Instrumentation | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 3 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Characteristics of Sensors, Flow rate Measurement Principles, Orifice-Meter, Venturi-Meter, Coriolis Flow Meter, Turbine Flow Meter, Rotameter, Velocity Measurements, Pitot Tube, Vane Anemometer, Hot Wire Anemometer, Laser Doppler Anemometer, Particle Image Velocimetry, Pressure Measurement, Manometer, Bourdon Tube Gauge, Piezoelectric Sensor, Temperature Measurement, Thermometer, Thermocouple, Thermistor, Optical Pyrometer, Rotational Speed Meters, Tachometer, Torque Measurement, Strain Gauges, Gas Analysis, Electro-Chemical Gas Analyzer, Accuracy, Precision, Statistical Methods Error Analysis and Uncertainty. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 5 | |||||||||
Mechanical Power Engineering |
3 | 5 | |||||||||
Automotive Engineering |
3 | 6 | |||||||||
Mechatronics Engineering |
3 | 5 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP331 | Digital Control | 2 CH | |||||||||
Prerequisites | ( MCT211 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Introduction to Digital Control: Types of Control Signals: Analog, Discrete and Digital. Discrete-Time Systems: Difference Equation and Z-Transform, Pulse Transfer Function, Solution of Difference Equation for Open and Closed Systems. Modelling of Digital Control Systems. State Space Representation. Sampling Techniques, Analogue to Digital and Digital to Analogue Converters, Data Acquisition. Programmable Logic Controllers: Logic Gates, Ladder Diagram, Application to Pneumatic Circuits. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP331s | Digital Control | 2 CH | |||||||||
Prerequisites | ( MCT211s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Introduction to Digital Control: Types of Control Signals: Analog, Discrete and Digital. Discrete-Time Systems: Difference Equation and Z-Transform, Pulse Transfer Function, Solution of Difference Equation for Open and Closed Systems. Modelling of Digital Control Systems. State Space Representation. Sampling Techniques, Analogue to Digital and Digital to Analogue Converters, Data Acquisition. Programmable Logic Controllers: Logic Gates, Ladder Diagram, Application to Pneumatic Circuits. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP332 | Process Control | 3 CH | |||||||||
Prerequisites | ( MEP331 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Process Control Principles and Applications: Dynamic Behaviour of Linear and Non-Linear First- and Second-Order Systems. Sensors and Actuators. Signal Conditioning Circuits: Filters, Instrumentation Amplifiers and Power Circuits. Process Flow Diagram (PFD). Piping and Instrumentation Drawing (P and ID). The Dynamics and Control of Real Processes: Heat Exchangers, Boilers, Internal Combustion Engines, Turbines. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP332s | Process Control | 3 CH | |||||||||
Prerequisites | ( MEP331s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Process Control Principles and Applications: Dynamic Behaviour of Linear and Non-Linear First- and Second-Order Systems. Sensors and Actuators. Signal Conditioning Circuits: Filters, Instrumentation Amplifiers and Power Circuits. Process Flow Diagram (PFD). Piping and Instrumentation Drawing (P and ID). The Dynamics and Control of Real Processes: Heat Exchangers, Boilers, Internal Combustion Engines, Turbines. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
3 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP431 | Fire Fighting | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Definition the Fire Fighting System, Classification of Occupancies, Types of Sprinkler Systems, Types of Sprinklers, Dry Pipe Sprinkler System, Deluge and Pre-Action System, Refrigerated Spaces, Commercial Type Cooking Equipment, Wet-Pipe Sprinkler System, Basic Design of Sprinkler Systems, How to Design a Project, Sprinkler Distribution inside the Places, Water Network Distribution and Sizing, Hydraulic Calculation Procedures –NFPA13. Using Hydraulic Calculation Program, Pumps Room, Control Stations, Testing and Commissioning, Extinguishing Agents and Portable Fire Extinguishers. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP431s | Fire Fighting | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Definition the Fire Fighting System, Classification of Occupancies, Types of Sprinkler Systems, Types of Sprinklers, Dry Pipe Sprinkler System, Deluge and Pre-Action System, Refrigerated Spaces, Commercial Type Cooking Equipment, Wet-Pipe Sprinkler System, Basic Design of Sprinkler Systems, How to Design a Project, Sprinkler Distribution inside the Places, Water Network Distribution and Sizing, Hydraulic Calculation Procedures –NFPA13. Using Hydraulic Calculation Program, Pumps Room, Control Stations, Testing and Commissioning, Extinguishing Agents and Portable Fire Extinguishers. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP432 | Computational Fluid Dynamics | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Governing Equations of the Reactive and Non-Reactive Flow Fields, Boundary and Initial Conditions, Finite Difference Approximations, Errors, Convergence, Mesh Dependency Analysis, Stability and Consistency, Discretization, Order of Accuracy and Discretization Schemes, Stability and Convergence Criterion, Control Volume Approach, Conduction Heat Transfer across a Plate, Effect of Flow Advection on the Temperature Distribution, Examples of Advection and Diffusion Partial Differential Equations in Heat Transfer and Fluid Mechanics, Source Terms, Jet Flow, Jet Flow with Chemical Reaction, Simple Turbulence Models, Advantages and Disadvantages of Numerical Solutions. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP432s | Computational Fluid Dynamics | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Governing Equations of the Reactive and Non-Reactive Flow Fields, Boundary and Initial Conditions, Finite Difference Approximations, Errors, Convergence, Mesh Dependency Analysis, Stability and Consistency, Discretization, Order of Accuracy and Discretization Schemes, Stability and Convergence Criterion, Control Volume Approach, Conduction Heat Transfer across a Plate, Effect of Flow Advection on the Temperature Distribution, Examples of Advection and Diffusion Partial Differential Equations in Heat Transfer and Fluid Mechanics, Source Terms, Jet Flow, Jet Flow with Chemical Reaction, Simple Turbulence Models, Advantages and Disadvantages of Numerical Solutions. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP433 | Management of Mechanical Power Projects | 3 CH | |||||||||
Prerequisites | ( MEP314 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Mechanical Engineering Projects, Project Classification, Collection of Projects Data, Statistical Analysis of Project Data, Project Finance, Project Budgeting, Bottle Necks of Projects, Asset Management, Facility Management, Equipment Depreciation, Failure and Anticipated Outage, Project Failure Modes, Project Requirements for Success, Estimation of Expenditure, Case Studies, Major Mechanical Projects, Mega Projects and Minor Projects, Utilization of Resources, Ware House Management and its Relation to Project Success, Project Management Techniques. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP433s | Management of Mechanical Power Projects | 3 CH | |||||||||
Prerequisites | ( MEP314s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Mechanical Engineering Projects, Project Classification, Collection of Projects Data, Statistical Analysis of Project Data, Project Finance, Project Budgeting, Bottle Necks of Projects, Asset Management, Facility Management, Equipment Depreciation, Failure and Anticipated Outage, Project Failure Modes, Project Requirements for Success, Estimation of Expenditure, Case Studies, Major Mechanical Projects, Mega Projects and Minor Projects, Utilization of Resources, Ware House Management and its Relation to Project Success, Project Management Techniques. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP434 | Water Desalination and Distillation | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Water Resources Management, Composition of Saline Water, Salinity Levels, Primitive Treatment of Saline Water, Thermal and Membrane Separation of Salts, Post Treatment of Water, Single Effect Evaporation, Single Effect Evaporation with Vapor Compression, Single Effect Evaporation with Mechanical Compression, Single Stage Flashing Desalination, Multi-Stage Flashing Desalination, Reverse Osmosis, Solar Stills, Desalination by Freezing, Cost Consideration, Desalination via Electro Dialysis. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP434s | Water Desalination and Distillation | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Water Resources Management, Composition of Saline Water, Salinity Levels, Primitive Treatment of Saline Water, Thermal and Membrane Separation of Salts, Post Treatment of Water, Single Effect Evaporation, Single Effect Evaporation with Vapor Compression, Single Effect Evaporation with Mechanical Compression, Single Stage Flashing Desalination, Multi-Stage Flashing Desalination, Reverse Osmosis, Solar Stills, Desalination by Freezing, Cost Consideration, Desalination via Electro Dialysis. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP435 | Design of Mechanical Power Units | 3 CH | |||||||||
Prerequisites | ( MDP211 ) AND ( MDP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Thermal Stresses across Boiler Vessels, Tube Sizing of Fire Tube Boilers and Water Tube Boilers, Axial Thrust Bearing and Journal Bearing of Centrifugal Pumps, Creep and Thermal Stresses in Steam Turbines, Selection of the Material and Diameter of Steam Turbine Shafts, Thermal Stresses in Internal Combustion Engines, Selection of the Material and Diameter of Gasoline and Diesel Engine Cylinders, Determination of the Thickness of Engine Cylinders, Design Consideration for Casting and Producing the Profile Shapes of Centrifugal Compressors, Selection of Axial Thrust and Journal Bearings of Axial Flow Compressors, Thermal Stresses and Deformation of Gas Turbine Nozzles, Thermal Stresses in Gas Turbine Blades and Selection of the Turbine Shaft Diameter and Blade Height. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP435s | Design of Mechanical Power Units | 3 CH | |||||||||
Prerequisites | ( MDP211s ) AND ( MDP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Thermal Stresses across Boiler Vessels, Tube Sizing of Fire Tube Boilers and Water Tube Boilers, Axial Thrust Bearing and Journal Bearing of Centrifugal Pumps, Creep and Thermal Stresses in Steam Turbines, Selection of the Material and Diameter of Steam Turbine Shafts, Thermal Stresses in Internal Combustion Engines, Selection of the Material and Diameter of Gasoline and Diesel Engine Cylinders, Determination of the Thickness of Engine Cylinders, Design Consideration for Casting and Producing the Profile Shapes of Centrifugal Compressors, Selection of Axial Thrust and Journal Bearings of Axial Flow Compressors, Thermal Stresses and Deformation of Gas Turbine Nozzles, Thermal Stresses in Gas Turbine Blades and Selection of the Turbine Shaft Diameter and Blade Height. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP241 | Technical Installations | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 0 Hours | |||||||||
Required SWL | 75 | Equivalent ECTS | 3 | ||||||||
Course Content | |||||||||||
Preliminary Studies for Plumbing, Installations, Design of Water Supply and Drainage Systems, Water Pipe Sizing, Fire Fighting, Sprinkler Systems, Special Structures, Industrial Control of Thermal Environments, Design Criteria and Sustainability for Architectural Conditions, Effects of Shading on the Air Conditioning Thermal Loads, Distribution and Integration of Air Conditioning Exits with Other Building Systems, Air Grilles and Diffusers in Suspended Ceiling. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Landscape Architecture |
2 | 5 | |||||||||
Housing Architecture and Urban Development |
1 | 5 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MEP241s | Technical Installations | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 0 Hours | |||||||||
Required SWL | 75 | Equivalent ECTS | 3 | ||||||||
Course Content | |||||||||||
Preliminary Studies for Plumbing, Installations, Design of Water Supply and Drainage Systems, Water Pipe Sizing, Fire Fighting, Sprinkler Systems, Special Structures, Industrial Control of Thermal Environments, Design Criteria and Sustainability for Architectural Conditions, Effects of Shading on the Air Conditioning Thermal Loads, Distribution and Integration of Air Conditioning Exits with Other Building Systems, Air Grilles and Diffusers in Suspended Ceiling. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Architectural Engineering |
2 | 6 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MEP341 | Refrigeration and Air Conditioning | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND (MEP221) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Refrigeration: Theoretical Refrigeration Vapor-Compression Cycles, Actual Refrigeration Vapor-Compression Cycles. Multi-Stage Compression Systems, Different Types of Components of Refrigeration Systems, Refrigerants, Cooling Load for Cold Stores. Performance and Selection of Refrigerating Equipment, Control of Refrigeration Capacity, Absorption Refrigeration. Miscellaneous Refrigeration Systems. Air Conditioning: Requirements of Air Conditioning, Filed of Application, Properties of Moist Air, Construction of Psychrometric Chart. Psychrometric Processes. Summer Air Conditioning Cycles. Winter Air Conditioning Cycles. All Year Conditioning Cycles, Air Conditioning Cooling and Heating Load Calculations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
5 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP341s | Refrigeration and Air Conditioning | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Refrigeration: Theoretical Refrigeration Vapor-Compression Cycles, Actual Refrigeration Vapor-Compression Cycles. Multi-Stage Compression Systems, Different Types of Components of Refrigeration Systems, Refrigerants, Cooling Load for Cold Stores. Performance and Selection of Refrigerating Equipment, Control of Refrigeration Capacity, Absorption Refrigeration. Miscellaneous Refrigeration Systems. Air Conditioning: Requirements of Air Conditioning, Field of Application, Properties of Moist Air, Construction of Psychrometric Chart. Psychrometric Processes. Summer Air Conditioning Cycles. Winter Air Conditioning Cycles. All Year Conditioning Cycles, Air Conditioning Cooling and Heating Load Calculations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP342 | HVAC System Design | 2 CH | |||||||||
Prerequisites | ( MEP213 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Principles of HVAC system design and analysis, load estimation. Sustainable design issues and impact on environment, HVAC types and components. HVAC system selection criteria including room air distribution, fans and air circulation, Psychrometric charts and processes such as humidifying and dehumidifying processes, Air ducting design. Air quality standards and thermal comfort. HVAC Control systems and techniques, operational economics, computer applications for load calculations and air ducting design. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Building Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MEP342s | HVAC System Design | 2 CH | |||||||||
Prerequisites | ( MEP213s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Principles of HVAC system design and analysis, load estimation. Sustainable design issues and impact on environment, HVAC types and components. HVAC system selection criteria including room air distribution, fans and air circulation, Psychrometric charts and processes such as humidifying and dehumidifying processes, Air ducting design. Air quality standards and thermal comfort. HVAC Control systems and techniques, operational economics, computer applications for load calculations and air ducting design. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP441 | Applied Building Services Technology | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Mechanical Systems Including HVAC (Heating Ventilation and Air Conditioning Systems), Plumbing Systems, and Fire-Fighting Systems. Piping Systems for Chilled Water, Piping Systems for Hot and Cold-Water Supply, Drainage and Fire-Fighting, Building Service and Energy System Design for High-Performance Buildings (such as Passive, Near-Zero-Energy and Positive Energy Buildings). Dealing with Plumbing Codes, Fire-Fighting Codes, HVAC Codes. Methods and Tools for Evaluating and Visualizing the Indoor Climate and Energy Performance of Buildings (e.g. Revit Software). Use of Simulation Tools (e.g. IDA ICE) for Evaluating the Indoor Climate and Energy Performance of Buildings in Relation to Certification Schemes such as LEED, and BREEAM. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP441s | Applied Building Services Technology | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Mechanical Systems Including HVAC (Heating Ventilation and Air Conditioning Systems), Plumbing Systems, and Fire-Fighting Systems. Piping Systems for Chilled Water, Piping Systems for Hot and Cold-Water Supply, Drainage and Fire-Fighting, Building Service and Energy System Design for High-Performance Buildings (such as Passive, Near-Zero-Energy and Positive Energy Buildings). Dealing with Plumbing Codes, Fire-Fighting Codes, HVAC Codes. Methods and Tools for Evaluating and Visualizing the Indoor Climate and Energy Performance of Buildings (e.g. Revit Software). Use of Simulation Tools (e.g. IDA ICE) for Evaluating the Indoor Climate and Energy Performance of Buildings in Relation to Certification Schemes such as LEED, and BREEAM. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
5 | 2 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP442 | Thermodynamics of Materials | 3 CH | |||||||||
Prerequisites | ( MEP221 ) AND ( MEP321 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Gas Pipeline, Liquid Pipeline. Mechanical Design of Pipelines: Thickness Calculation, Surge Assessment, Thermal Expansion, Support System Design. Coatings, Painting, Lining, Warping, Cathodic Protection System. Non-Metallic and Metallic Construction of Pipelines, Batch Operation, Handling Various Products. Pigging Scenarios: Above Ground, Buried, Submarine, Through Tunnels. Corrosion: Corrosive and Non-Corrosive Services, Lifetime Expectancy. Operation Scenarios, Surveillance and Monitoring Level. Field of Application: Petrochemical, Refinery, Gas Plant, Fertilizer Plants, Water, Seawater, General Industry. Hydrostatic Testing. Control Valves and Pipe Fittings. Maintenance: Planning for Oil Pipeline Spills. Leak Detection. Rehabilitation: Risk Evaluation. Codes, Specifications and Standard Pipe Details. Piping and Tubing Material. Piping Systems and Plant Utility. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP442s | Thermodynamics of Materials | 3 CH | |||||||||
Prerequisites | ( MEP221s ) AND ( MEP321s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Gas Pipeline, Liquid Pipeline. Mechanical Design of Pipelines: Thickness Calculation, Surge Assessment, Thermal Expansion, Support System Design. Coatings, Painting, Lining, Warping, Cathodic Protection System. Non-Metallic and Metallic Construction of Pipelines, Batch Operation, Handling Various Products. Pigging Scenarios: Above Ground, Buried, Submarine, Through Tunnels. Corrosion: Corrosive and Non-Corrosive Services, Lifetime Expectancy. Operation Scenarios, Surveillance and Monitoring Level. Field of Application: Petrochemical, Refinery, Gas Plant, Fertilizer Plants, Water, Seawater, General Industry. Hydrostatic Testing. Control Valves and Pipe Fittings. Maintenance: Planning for Oil Pipeline Spills. Leak Detection. Rehabilitation: Risk Evaluation. Codes, Specifications and Standard Pipe Details. Piping and Tubing Material. Piping Systems and Plant Utility. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP443 | Petroleum Pipelines | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
First and Second Laws Analyses of Thermal Systems. Energy Analysis of Power Cycles, the Cost of Electrical Power Generation, Selection of the Type of Generation Unit, Performance and Operational Characteristics of Power Plants, Load Sharing among Generators. Interest and Depreciation, Present Worth, and Annual Worth. Cost, Levelizing Equations, Economic Evaluation Methods. Construction Cost, Operation and Maintenance Costs, Cogeneration, Economic Scheduling Principles, Load Distribution, Variation of Station Cost with Size of Unit. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP443s | Petroleum Pipelines | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
First and Second Laws Analyses of Thermal Systems. Energy Analysis of Power Cycles, the Cost of Electrical Power Generation, Selection of the Type of Generation Unit, Performance and Operational Characteristics of Power Plants, Load Sharing among Generators. Interest and Depreciation, Present Worth, and Annual Worth. Cost, Levelizing Equations, Economic Evaluation Methods. Construction Cost, Operation and Maintenance Costs, Cogeneration, Economic Scheduling Principles, Load Distribution, Variation of Station Cost with Size of Unit. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP444 | Economics of Energy Conversion | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Definition of Environment. Human Effects of Projects: Development, Economical Effects, Social Effects, Cultural Effects, Aesthetics Effects, Healthy and Psychological Effects. Types of Projects: Building Projects: Residential, Touristic, Commercial and General Building. Projects of General Facilities: Power Stations, Water Treatment, Water Supply and Wastewater Network. Road and Railway Networks, Reservoirs, Dams, Canals and Drains. Different Industrial Project: Textures, Iron, Cement, Carpets, Ceramics and Food Industries. Electrical Devices and Automotive Industries. Impact of Projects on the Surroundings: Negative and Positive Impact, Direct and Indirect Effects, Evaluation of Different Experiments: Local and International Strategies to Avoid Negative Impact of Projects on the Environment, Permissible Limits for Agreement of Project with the Environment. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP444s | Economics of Energy Conversion | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Definition of Environment. Human Effects of Projects: Development, Economical Effects, Social Effects, Cultural Effects, Aesthetics Effects, Healthy and Psychological Effects. Types of Projects: Building Projects: Residential, Touristic, Commercial and General Building. Projects of General Facilities: Power Stations, Water Treatment, Water Supply and Wastewater Network. Road and Railway Networks, Reservoirs, Dams, Canals and Drains. Different Industrial Project: Textures, Iron, Cement, Carpets, Ceramics and Food Industries. Electrical Devices and Automotive Industries. Impact of Projects on the Surroundings: Negative and Positive Impact, Direct and Indirect Effects, Evaluation of Different Experiments: Local and International Strategies to Avoid Negative Impact of Projects on the Environment, Permissible Limits for Agreement of Project with the Environment. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP445 | Environmental Impact of Mechanical Power Projects | 3 CH | |||||||||
Prerequisites | ( MEP342 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Air conditioning systems and classifications, Air terminal units (air handling units, fan coil units), Sections of air handling units (filters, cooling and dehumidifying coils, heating coils, Humidifiers, Fans), Chillers (air cooled chillers, water cooled chillers, absorption chillers) cooling towers, condensing units and its components, unitary air conditioning units, Desiccant dehumidifiers, Chilled water networks and pumps, energy recovery systems, expansion devices and cold stores. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP445s | Environmental Impact of Mechanical Power Projects | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Air conditioning systems and classifications, Air terminal units (air handling units, fan coil units), Sections of air handling units (filters, cooling and dehumidifying coils, heating coils, Humidifiers, Fans), Chillers (air cooled chillers, water cooled chillers, absorption chillers) cooling towers, condensing units and its components, unitary air conditioning units, Desiccant dehumidifiers, Chilled water networks and pumps, energy recovery systems, expansion devices and cold stores. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP451 | Nuclear Energy | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MEP221 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
This is an Introductory Course in Nuclear Engineering with Focus on Energy Conversion Aspects, Safety Systems and Sustainability of Nuclear Energy. The Course Starts with an Introduction on Nuclear Energy Policy and Regulation; then Moves on to Applied Nuclear Physics Covering Fission and Fusion Energy, Thermal Effects of Decaying Isotopes and Reaction Cross-Section. This is Followed by a Study of Thermal and Fast Reactors Covering Pressurized Water Reactors, Boiling Water Reactors, Gas Cooled Reactors and Fast Breeders Including Passive and Active Control and Safety Systems. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP451s | Nuclear Energy | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MEP221s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
This is an Introductory Course in Nuclear Engineering with Focus on Energy Conversion Aspects, Safety Systems and Sustainability of Nuclear Energy. The Course Starts with an Introduction on Nuclear Energy Policy and Regulation; then Moves on to Applied Nuclear Physics Covering Fission and Fusion Energy, Thermal Effects of Decaying Isotopes and Reaction Cross-Section. This is Followed by a Study of Thermal and Fast Reactors Covering Pressurized Water Reactors, Boiling Water Reactors, Gas Cooled Reactors and Fast Breeders Including Passive and Active Control and Safety Systems. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP452 | Thermal Aspects of Nuclear Reactors | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Fluid Dynamics and Heat Transfer, Thermal and Hydraulic Analysis of Nuclear Reactors, Two-Phase Flow and Boiling, Compressible Flow, Stress Analysis, Energy Conversion Methods, Critical Heat Flux across Steam Boiler Walls. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP452s | Thermal Aspects of Nuclear Reactors | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Fluid Dynamics and Heat Transfer, Thermal and Hydraulic Analysis of Nuclear Reactors, Two-Phase Flow and Boiling, Compressible Flow, Stress Analysis, Energy Conversion Methods, Critical Heat Flux across Steam Boiler Walls. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP453 | Nuclear Reactions and Interaction with Matter | 3 CH | |||||||||
Prerequisites | ( MEP211 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Interaction of Gamma Rays, Neutrons, and Charged Particles with Matter, Nuclear Structure and Radioactive Decay, Cross Sections and Energies of Nuclear Reactions, Nuclear Fission and The Fission Products, Fission and Fusion Reactions as Energy Sources. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP453s | Nuclear Reactions and Interaction with Matter | 3 CH | |||||||||
Prerequisites | ( MEP211s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Interaction of Gamma Rays, Neutrons, and Charged Particles with Matter, Nuclear Structure and Radioactive Decay, Cross Sections and Energies of Nuclear Reactions, Nuclear Fission and The Fission Products, Fission and Fusion Reactions as Energy Sources. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP454 | Radioactive Waste Management | 3 CH | |||||||||
Prerequisites | ( MEP212 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Components and Material Flow Sheets for Nuclear Fuel Cycle, Waste Characteristics, Sources of Radioactive Wastes, Composition, Radioactivity and Heat Generation, Waste Treatment Technologies, Waste Disposal Technologies, Safety Assessment of Waste Disposal. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP454s | Radioactive Waste Management | 3 CH | |||||||||
Prerequisites | ( MEP212s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Components and Material Flow Sheets for Nuclear Fuel Cycle, Waste Characteristics, Sources of Radioactive Wastes, Composition, Radioactivity and Heat Generation, Waste Treatment Technologies, Waste Disposal Technologies, Safety Assessment of Waste Disposal. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP455 | Methods of Nuclear Risk Analysis | 3 CH | |||||||||
Prerequisites | ( MEP314 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Methodological Approaches for the Quantification of Technological Risk and Risk Based Decision Making. Probabilistic Safety Assessment, Human Health Risks, Environmental and Ecological Risk Analysis. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP455s | Methods of Nuclear Risk Analysis | 3 CH | |||||||||
Prerequisites | ( MEP314s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Methodological Approaches for the Quantification of Technological Risk and Risk Based Decision Making. Probabilistic Safety Assessment, Human Health Risks, Environmental and Ecological Risk Analysis. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MEP491 | Mechanical Power Graduation Project (1) | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 4 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Selection of a Thermo-Fluid System which is Encountered in the Practical Field, Discussion of the Various Tools by which the Engineer actively Quantifies and Controls the Performance of the System, Determination of the Working Parameters that Affect the Performance of the System, Identifying the Mutual Relationships among the Different Components of the System. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP491s | Mechanical Power Graduation Project (1) | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 4 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Selection of a Thermo-Fluid System which is Encountered in the Practical Field, Discussion of the Various Tools by which the Engineer actively Quantifies and Controls the Performance of the System, Determination of the Working Parameters that Affect the Performance of the System, Identifying the Mutual Relationships among the Different Components of the System. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MEP492 | Mechanical Power Graduation Project (2) | 3 CH | |||||||||
Prerequisites | ( MEP491 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 4 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Designing the Prototype of the Elements under Investigation, Testing under Variable Conditions, Construction of the Operational Maps of the Different Components, Simulation of the System Behaviour using CFD codes, Evaluating the System Performance under Transient and Steady State Steady Flow Conditions, Suggesting the Potential Methods for Improving the System Design and Operation. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MEP492s | Mechanical Power Graduation Project (2) | 3 CH | |||||||||
Prerequisites | ( MEP491s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 2 Hours | 4 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Designing the Prototype of the Elements under Investigation, Testing under Variable Conditions, Construction of the Operational Maps of the Different Components, Simulation of the System Behaviour using CFD codes, Evaluating the System Performance under Transient and Steady State Steady Flow Conditions, Suggesting the Potential Methods for Improving the System Design and Operation. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechanical Power Engineering |
4 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |