Courses offered by Design and Production Engineering Department
The Design and Production Engineering Department is responsible for teaching courses that serve the following programs:
- Several Basic Engineering courses as a Faculty Requirement.
- Several Basic Mechanical Engineering courses as a Mechanical Discipline Requirement.
- Design and Production Engineering Program.
- Materials Engineering Program.
- Manufacturing Engineering Program.
- Energy and Renewable Energy Engineering Program.
Table 44 List of specializations at the Design and Production Engineering Department.
# | Specialization |
0 | Graduation Projects |
1 | Design and Dynamics |
3 | Industrial Engineering |
5 | Material Engineering |
8 | Manufacturing |
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 45 List of MDP 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 | MDP355 | Modern Iron and Steel Making | 2 | 5 | 125 | 2 | 1 | 0 | 3 | 30 | 25 | 0 | 40 | ( MDP254 ) AND ( MDP256 ) | ||||||
0. Graduation Projects | ||||||||||||||||||||
1 | 4 | MDP401 | Mechanical Design & Production Graduation Project (1) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 40 | 0 | |||||
1 | 4 | MDP401s | Mechanical Design & Production Graduation Project (1) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 50 | 0 | 0 | 50 | |||||
1 | 4 | MDP402 | Mechanical Design & Production Graduation Project (2) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 40 | 0 | ( MDP401 ) | ||||
1 | 4 | MDP402s | Mechanical Design & Production Graduation Project (2) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 50 | 0 | 0 | 50 | ( MDP401s ) | ||||
1 | 4 | MDP403 | Materials Engineering Graduation Project (1) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 40 | 0 | ( MDP354 ) | ||||
1 | 4 | MDP403s | Materials Engineering Graduation Project (1) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 0 | 40 | ( MDP354s ) | ||||
1 | 4 | MDP404 | Materials Engineering Graduation Project (2) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 40 | 0 | ( MDP403 ) | ||||
1 | 4 | MDP404s | Materials Engineering Graduation Project (2) | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 0 | 40 | ( MDP403s ) | ||||
1. Design and Dynamics | ||||||||||||||||||||
1 | 0 | MDP011 | Engineering Drawing | 3 | 6 | 150 | 1 | 3 | 2 | 6 | x | 35 | 20 | 0 | 40 | |||||
1 | 0 | MDP011s | Engineering Drawing | 3 | 6 | 150 | 1 | 3 | 2 | 6 | x | 40 | 20 | 0 | 40 | |||||
1 | 1 | MDP111 | Mechanical Engineering Drawing | 3 | 6 | 150 | 1 | 3 | 2 | 6 | x | 20 | 25 | 10 | 40 | ( MDP011 ) | ||||
1 | 1 | MDP111s | Mechanical Engineering Drawing | 3 | 6 | 150 | 1 | 3 | 2 | 6 | x | 20 | 25 | 15 | 40 | ( MDP011s ) | ||||
1 | 1 | MDP112 | Machine Construction | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 15 | 40 | ( MDP111 ) | ||||
1 | 1 | MDP112s | Machine Construction | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 25 | 25 | 0 | 50 | ( MDP111s ) | ||||
1 | 2 | MDP211 | Machine Elements Design | 4 | 8 | 200 | 3 | 2 | 2 | 7 | x | 35 | 20 | 0 | 40 | ( MDP112 ) | ||||
1 | 2 | MDP211s | Machine Elements Design | 4 | 8 | 200 | 3 | 2 | 2 | 7 | x | 40 | 20 | 0 | 40 | ( MDP112s ) | ||||
1 | 2 | MDP212 | Mechanics of Machines | 4 | 6 | 150 | 3 | 3 | 1 | 7 | x | 30 | 15 | 10 | 40 | ( PHM131 ) | ||||
1 | 2 | MDP212s | Mechanics of Machines | 4 | 6 | 150 | 3 | 3 | 1 | 7 | x | 25 | 15 | 0 | 60 | ( PHM131s ) | ||||
1 | 3 | MDP311 | Mechanical Vibrations | 4 | 7 | 175 | 3 | 2 | 1 | 6 | x | 15 | 25 | 10 | 40 | ( PHM131 ) | ||||
1 | 3 | MDP311s | Mechanical Vibrations | 4 | 7 | 175 | 3 | 2 | 1 | 6 | x | 25 | 15 | 0 | 60 | ( PHM131s ) | ||||
1 | 3 | MDP312 | Mechanical System Design | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 15 | 25 | 10 | 40 | ( MDP211 ) | ||||
1 | 3 | MDP312s | Mechanical System Design | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 60 | 0 | 0 | 40 | ( MDP211s ) | ||||
1 | 4 | MDP411 | Introduction to Finite Elements | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 45 | 20 | 0 | 30 | ( PHM112 ) AND ( MDP112 ) | ||||
1 | 4 | MDP411s | Introduction to Finite Elements | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 50 | 20 | 0 | 30 | ( PHM112s ) AND ( MDP112s ) | ||||
1 | 4 | MDP412 | Noise & Vibration Control | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MDP312 ) | ||||
1 | 4 | MDP412s | Noise & Vibration Control | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 20 | 20 | 0 | 60 | ( MDP312s ) | ||||
1 | 4 | MDP413 | Design Optimization | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( PHM112 ) AND ( MDP211 ) | ||||
1 | 4 | MDP413s | Design Optimization | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 20 | 20 | 20 | 40 | ( PHM112s ) AND ( MDP211s ) | ||||
1 | 4 | MDP414 | Product Design & Development | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 35 | 20 | 0 | 40 | |||||
1 | 4 | MDP414s | Product Design & Development | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 40 | 20 | 0 | 40 | |||||
1 | 4 | MDP415 | Selected Topics in Mechanical Design | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MDP312 ) | ||||
1 | 4 | MDP415s | Selected Topics in Mechanical Design | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 40 | 20 | 0 | 40 | ( MDP312s ) | ||||
3. Industrial Engineering | ||||||||||||||||||||
1 | 2 | MDP231 | Engineering Economy | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 30 | 25 | 0 | 40 | |||||
1 | 2 | MDP231s | Engineering Economy | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 35 | 25 | 0 | 40 | |||||
1 | 2 | MDP232 | Industrial Project Management | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 30 | 25 | 0 | 40 | |||||
1 | 2 | MDP232s | Industrial Project Management | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 35 | 25 | 0 | 40 | |||||
1 | 2 | MDP233 | Work Study and Plant Layout | 4 | 6 | 150 | 3 | 2 | 0 | 5 | x | 30 | 25 | 0 | 40 | ( PHM111 ) | ||||
1 | 2 | MDP233s | Work Study and Plant Layout | 4 | 6 | 150 | 3 | 2 | 0 | 5 | x | 35 | 25 | 0 | 40 | ( PHM111s ) | ||||
1 | 3 | MDP331 | Maintenance Planning and Scheduling | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 30 | 25 | 0 | 40 | |||||
1 | 3 | MDP331s | Maintenance Planning and Scheduling | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 35 | 25 | 0 | 40 | |||||
1 | 3 | MDP332 | Work Study | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( PHM111 ) | ||||
1 | 3 | MDP332s | Work Study | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( PHM111s ) | ||||
1 | 3 | MDP333 | Operations Research | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( PHM013 ) AND ( PHM111 ) | ||||
1 | 3 | MDP333s | Operations Research | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( PHM013s ) AND ( PHM111s ) | ||||
1 | 3 | MDP334 | Principles of Operations Management | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP331 ) | ||||
1 | 3 | MDP334s | Principles of Operations Management | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP331s ) | ||||
1 | 3 | MDP335 | Production Planning and Scheduling | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 30 | 25 | 0 | 40 | ( MDP334 ) | ||||
1 | 3 | MDP335s | Production Planning and Scheduling | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 35 | 25 | 0 | 40 | ( MDP334s ) | ||||
1 | 3 | MDP336 | Facilities Layout and Design | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP233 ) | ||||
1 | 3 | MDP336s | Facilities Layout and Design | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP233s ) | ||||
1 | 4 | MDP431 | Operations Management | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MDP231 ) | ||||
1 | 4 | MDP431s | Operations Management | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP231s ) | ||||
1 | 4 | MDP432 | Facilities Planning | 3 | 7 | 175 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MDP332 ) AND ( MDP333 ) | ||||
1 | 4 | MDP432s | Facilities Planning | 3 | 7 | 175 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP332s ) AND ( MDP333s ) | ||||
1 | 4 | MDP433 | Quality Control | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( PHM111 ) | ||||
1 | 4 | MDP433s | Quality Control | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( PHM111s ) | ||||
1 | 4 | MDP434 | Quality Systems & Assurance | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( PHM111 ) | ||||
1 | 4 | MDP434s | Quality Systems & Assurance | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( PHM111s ) | ||||
1 | 4 | MDP435 | Industrial Systems Modeling & Simulation | 3 | 6 | 150 | 2 | 0 | 3 | 5 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MDP435s | Industrial Systems Modeling & Simulation | 3 | 6 | 150 | 2 | 0 | 3 | 5 | x | 50 | 0 | 50 | 0 | |||||
1 | 4 | MDP436 | Production Planning & Control | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MDP431 ) | ||||
1 | 4 | MDP436s | Production Planning & Control | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP431s ) | ||||
1 | 4 | MDP437 | Ergonomics | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MDP332 ) | ||||
1 | 4 | MDP437s | Ergonomics | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | |||||
1 | 4 | MDP438 | Simulation of Manufacturing Systems | 3 | 6 | 150 | 2 | 0 | 3 | 5 | x | 30 | 25 | 0 | 40 | ( MDP332 OR MDP233 ) | ||||
1 | 4 | MDP438s | Simulation of Manufacturing Systems | 3 | 6 | 150 | 2 | 0 | 3 | 5 | x | 35 | 25 | 0 | 40 | ( MDP332s OR MDP233s ) | ||||
1 | 4 | MDP439 | Lean Manufacturing Systems | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MPD334 ) | ||||
1 | 4 | MDP439s | Lean Manufacturing Systems | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MPD334s ) | ||||
1 | 4 | MDP440 | Quality Assurance and Six Sigma | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( PHM111 ) | ||||
1 | 4 | MDP440s | Quality Assurance and Six Sigma | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( PHM111s ) | ||||
1 | 4 | MDP441 | Industrial Technologies | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 45 | 10 | 0 | 40 | ( MDP233 ) | ||||
1 | 4 | MDP441s | Industrial Technologies | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 50 | 10 | 0 | 40 | ( MDP233s ) | ||||
5. Material Engineering | ||||||||||||||||||||
1 | 1 | MDP151 | Structures & Properties of Materials | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 20 | 25 | 10 | 40 | ( PHM041 ) | ||||
1 | 1 | MDP151s | Structures & Properties of Materials | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 25 | 25 | 10 | 40 | ( PHM041s ) | ||||
1 | 1 | MDP152 | Metallurgy & Material Testing | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 15 | 20 | 20 | 40 | ( MDP151 ) | ||||
1 | 1 | MDP152s | Metallurgy & Material Testing | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 10 | 10 | 20 | 60 | ( MDP151s ) | ||||
1 | 1 | MDP153 | Crystalline Structures of Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 20 | 25 | 10 | 40 | ( MDP151 ) | ||||
1 | 1 | MDP153s | Crystalline Structures of Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 25 | 25 | 10 | 40 | ( MDP151s ) | ||||
1 | 2 | MDP251 | Casting & Welding (1) | 3 | 4 | 100 | 2 | 2 | 1 | 5 | x | 35 | 10 | 10 | 40 | ( MDP152 ) | ||||
1 | 2 | MDP251s | Casting & Welding (1) | 3 | 4 | 100 | 2 | 2 | 1 | 5 | x | 20 | 10 | 10 | 60 | ( MDP152s ) | ||||
1 | 2 | MDP252 | Casting & Welding (2) | 2 | 4 | 100 | 2 | 0 | 2 | 4 | x | 30 | 25 | 0 | 40 | ( MDP251 ) | ||||
1 | 2 | MDP252s | Casting & Welding (2) | 2 | 4 | 100 | 2 | 0 | 2 | 4 | x | 35 | 25 | 0 | 40 | ( MDP251s ) | ||||
1 | 2 | MDP254 | Thermodynamics of Materials | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 20 | 25 | 10 | 40 | ( MEP111 ) | ||||
1 | 2 | MDP254s | Thermodynamics of Materials | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 25 | 25 | 10 | 40 | ( MEP111s ) | ||||
1 | 2 | MDP255 | Materials Testing and Behavior | 3 | 6 | 150 | 2 | 2 | 2 | 6 | x | 20 | 25 | 10 | 40 | ( MDP151 ) | ||||
1 | 2 | MDP255s | Materials Testing and Behavior | 3 | 6 | 150 | 2 | 2 | 2 | 6 | x | 25 | 25 | 10 | 40 | ( MDP151s ) | ||||
1 | 2 | MDP256 | Phase Transformation and Heat Treatment | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 20 | 25 | 10 | 40 | ( MDP152 OR MDP153 ) | ||||
1 | 2 | MDP256s | Phase Transformation and Heat Treatment | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 25 | 25 | 10 | 40 | ( MDP152s OR MDP153s ) | ||||
1 | 2 | MDP257 | Materials for Advanced Manufacturing Technology | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 20 | 25 | 10 | 40 | ( MDP183 ) | ||||
1 | 2 | MDP257s | Materials for Advanced Manufacturing Technology | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 25 | 25 | 10 | 40 | ( MDP183s ) | ||||
1 | 3 | MDP351 | Industrial Furnaces and Heat Treatment | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 30 | 25 | 0 | 40 | ( MDP152 ) | ||||
1 | 3 | MDP351s | Industrial Furnaces and Heat Treatment | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 35 | 25 | 0 | 40 | ( MDP152s ) | ||||
1 | 3 | MDP353 | Polymer Materials | 3 | 6 | 150 | 3 | 0 | 2 | 5 | x | 20 | 25 | 10 | 40 | ( PHM242 ) | ||||
1 | 3 | MDP353s | Polymer Materials | 3 | 6 | 150 | 3 | 0 | 2 | 5 | x | 25 | 25 | 10 | 40 | ( PHM242s ) | ||||
1 | 3 | MDP354 | Industrial Project | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 40 | 0 | ( MDP255 ) AND ( MDP256 ) | ||||
1 | 3 | MDP354s | Industrial Project | 3 | 6 | 150 | 1 | 0 | 6 | 7 | x | 60 | 0 | 0 | 40 | ( MDP255s ) AND ( MDP256s ) | ||||
1 | 3 | MDP355 | Modern Ferrous and Non-Ferrous Making | 2 | 5 | 125 | 2 | 1 | 0 | 3 | x | 30 | 25 | 0 | 40 | ( MDP254 ) AND ( MDP256 ) | ||||
1 | 3 | MDP355s | Modern Ferrous and Non-Ferrous Making | 2 | 5 | 125 | 2 | 1 | 0 | 3 | x | 35 | 25 | 0 | 40 | ( MDP254s ) AND ( MDP256s ) | ||||
1 | 3 | MDP356 | Glass, Ceramics, and Binding Materials | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP153 ) | ||||
1 | 3 | MDP356s | Glass, Ceramics, and Binding Materials | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP153s ) | ||||
1 | 4 | MDP451 | Failure Analysis | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 20 | 25 | 10 | 40 | ( MDP151 ) | ||||
1 | 4 | MDP451s | Failure Analysis | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 10 | 10 | 20 | 60 | ( MDP151s ) | ||||
1 | 4 | MDP452 | Material and Process Selection | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 15 | 20 | 20 | 40 | ( MDP081 ) | ||||
1 | 4 | MDP452s | Material and Process Selection | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 10 | 10 | 20 | 60 | ( MDP081s ) | ||||
1 | 4 | MDP453 | Composites Technology | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 15 | 20 | 20 | 40 | ( MDP151 ) | ||||
1 | 4 | MDP453s | Composites Technology | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 10 | 10 | 20 | 60 | ( MDP151s ) | ||||
1 | 4 | MDP454 | Corrosion | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 20 | 25 | 10 | 40 | ( MDP151 ) | ||||
1 | 4 | MDP454s | Corrosion | 3 | 5 | 125 | 3 | 0 | 1 | 4 | x | 10 | 10 | 20 | 60 | ( MDP151s ) | ||||
1 | 4 | MDP455 | Renewable Materials | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MDP455s | Renewable Materials | 3 | 5 | 125 | 2 | 2 | 2 | 6 | x | 50 | 10 | 0 | 40 | |||||
1 | 4 | MDP456 | Petrochemicals and Polymer Products | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 30 | 25 | 0 | 40 | ( PHM141 ) | ||||
1 | 4 | MDP456s | Petrochemicals and Polymer Products | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 35 | 25 | 0 | 40 | ( PHM141s ) | ||||
1 | 4 | MDP457 | Extractive Metallurgy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP183 ) AND ( MDP256 ) | ||||
1 | 4 | MDP457s | Extractive Metallurgy | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP183s ) AND ( MDP256s ) | ||||
1 | 4 | MDP458 | Material and Process Selection | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 15 | 25 | 10 | 40 | ( MDP081 ) | ||||
1 | 4 | MDP458s | Material and Process Selection | 2 | 4 | 100 | 2 | 1 | 0 | 3 | x | 30 | 20 | 0 | 50 | ( MDP081s ) | ||||
1 | 4 | MDP459 | Corrosion Control and Cathodic Protection | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP451 ) AND ( MDP454 ) | ||||
1 | 4 | MDP459s | Corrosion Control and Cathodic Protection | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP451s ) AND ( MDP454s ) | ||||
1 | 4 | MDP460 | Non-destructive Testing of Materials (1) | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP255 ) | ||||
1 | 4 | MDP460s | Non-destructive Testing of Materials (1) | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP255s ) | ||||
1 | 4 | MDP461 | Non-destructive Testing of Materials (2) | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP460 ) | ||||
1 | 4 | MDP461s | Non-destructive Testing of Materials (2) | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP460s ) | ||||
1 | 4 | MDP462 | Polymeric Processing Techniques | 2 | 4 | 100 | 2 | 0 | 2 | 4 | x | 30 | 25 | 0 | 40 | MDP151 | ||||
1 | 4 | MDP462s | Polymeric Processing Techniques | 2 | 4 | 100 | 2 | 0 | 2 | 4 | x | 35 | 25 | 0 | 40 | |||||
1 | 4 | MDP463 | Materials for Energy Solution | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP212 ) AND ( MDP353 ) | ||||
1 | 4 | MDP463s | Materials for Energy Solution | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MDP353s ) | ||||
1 | 4 | MDP464 | Surfactants and lubricating Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP212 ) AND ( MDP353 ) | ||||
1 | 4 | MDP464s | Surfactants and lubricating Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MDP353s ) | ||||
1 | 4 | MDP465 | Rubber and Sealing Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MEP212 ) AND ( MDP353 ) | ||||
1 | 4 | MDP465s | Rubber and Sealing Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MEP212s ) AND ( MDP353s ) | ||||
1 | 4 | MDP466 | Polymer Processing | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MDP353 ) | ||||
1 | 4 | MDP466s | Polymer Processing | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP353s ) | ||||
1 | 4 | MDP467 | Polymer Testing | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP353 ) | ||||
1 | 4 | MDP467s | Polymer Testing | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP353s ) | ||||
1 | 4 | MDP468 | Materials Characterization | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP255 ) | ||||
1 | 4 | MDP468s | Materials Characterization | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP255s ) | ||||
1 | 4 | MDP469 | Glasses Materials and Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP356 ) | ||||
1 | 4 | MDP469s | Glasses Materials and Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP356s ) | ||||
1 | 4 | MDP470 | Ceramic Materials and Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP356 ) | ||||
1 | 4 | MDP470s | Ceramic Materials and Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP356s ) | ||||
1 | 4 | MDP471 | Binding Materials and Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP356 ) | ||||
1 | 4 | MDP471s | Binding Materials and Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP356s ) | ||||
1 | 4 | MDP472 | Biomedical Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP356 ) | ||||
1 | 4 | MDP472s | Biomedical Materials | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP356s ) | ||||
1 | 4 | MDP473 | Introduction to Nano technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( PHM121 ) | ||||
1 | 4 | MDP473s | Introduction to Nano technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( PHM121s ) | ||||
8. Manufacturing | ||||||||||||||||||||
1 | 0 | MDP081 | Production Engineering | 3 | 5 | 125 | 2 | 0 | 3 | 5 | x | 20 | 25 | 10 | 40 | |||||
1 | 0 | MDP081s | Production Engineering | 3 | 5 | 125 | 2 | 0 | 3 | 5 | x | 25 | 15 | 10 | 50 | |||||
1 | 1 | MDP181 | Manufacturing Technology (1) | 3 | 5 | 125 | 3 | 0 | 2 | 5 | x | 15 | 25 | 15 | 40 | ( MDP081 ) | ||||
1 | 1 | MDP181s | Manufacturing Technology (1) | 3 | 5 | 125 | 3 | 0 | 2 | 5 | x | 20 | 25 | 15 | 40 | ( MDP081s ) | ||||
1 | 1 | MDP182 | Metal Forming Theory and Processes | 3 | 7 | 175 | 2 | 1 | 3 | 6 | x | 30 | 25 | 0 | 40 | ( MDP081 ) AND ( MDP151 ) | ||||
1 | 1 | MDP182s | Metal Forming Theory and Processes | 3 | 7 | 175 | 2 | 1 | 3 | 6 | x | 35 | 25 | 0 | 40 | ( MDP081s ) AND ( MDP151s ) | ||||
1 | 1 | MDP183 | Manufacturing Technologies | 4 | 6 | 150 | 3 | 2 | 2 | 7 | x | 20 | 25 | 10 | 40 | ( MDP081 ) | ||||
1 | 1 | MDP183s | Manufacturing Technologies | 4 | 6 | 150 | 3 | 2 | 2 | 7 | x | 25 | 25 | 10 | 40 | ( MDP081s ) | ||||
1 | 2 | MDP281 | Metal Cutting Theory and Technologies | 4 | 8 | 200 | 3 | 1 | 3 | 7 | x | 30 | 25 | 0 | 40 | ( MDP081 ) | ||||
1 | 2 | MDP281s | Metal Cutting Theory and Technologies | 4 | 8 | 200 | 3 | 1 | 3 | 7 | x | 35 | 25 | 0 | 40 | ( MDP081s ) | ||||
1 | 2 | MDP282 | Non-Conventional Processing | 2 | 4 | 100 | 2 | 0 | 2 | 4 | x | 30 | 25 | 0 | 40 | ( MDP182 ) AND ( PHM041 ) | ||||
1 | 2 | MDP282s | Non-Conventional Processing | 2 | 4 | 100 | 2 | 0 | 2 | 4 | x | 35 | 25 | 0 | 40 | ( MDP182s ) AND ( PHM041s ) | ||||
1 | 3 | MDP381 | Theory of Metal Forming | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 30 | 25 | 0 | 40 | ( MDP181 ) | ||||
1 | 3 | MDP381s | Theory of Metal Forming | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 35 | 25 | 0 | 40 | ( MDP181s ) | ||||
1 | 3 | MDP382 | Theory of Metal Cutting | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MDP181 ) | ||||
1 | 3 | MDP382s | Theory of Metal Cutting | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 35 | 25 | 0 | 40 | ( MDP181s ) | ||||
1 | 3 | MDP383 | Metal Forming Technology, Machines and Dies | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MDP181 ) | ||||
1 | 3 | MDP383s | Metal Forming Technology, Machines and Dies | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 35 | 25 | 0 | 40 | ( MDP181s ) | ||||
1 | 3 | MDP384 | Metal Cutting Machines and Technology | 3 | 6 | 150 | 2 | 2 | 2 | 6 | x | 15 | 25 | 10 | 40 | ( MDP181 ) AND ( MDP211 ) | ||||
1 | 3 | MDP384s | Metal Cutting Machines and Technology | 3 | 6 | 150 | 2 | 2 | 2 | 6 | x | 35 | 25 | 0 | 40 | ( MDP181s ) AND ( MDP211s ) | ||||
1 | 3 | MDP385 | Manufacturing Processes | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 30 | 25 | 0 | 40 | ( MDP182 ) AND ( MDP281 ) | ||||
1 | 3 | MDP385s | Manufacturing Processes | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 35 | 25 | 0 | 40 | ( MDP182s ) AND ( MDP281s ) | ||||
1 | 3 | MDP386 | Computer Aided Manufacturing | 3 | 6 | 150 | 2 | 0 | 3 | 5 | x | 30 | 25 | 0 | 40 | ( MDP281 ) | ||||
1 | 3 | MDP386s | Computer Aided Manufacturing | 3 | 6 | 150 | 2 | 0 | 3 | 5 | x | 35 | 25 | 0 | 40 | ( MDP281s ) | ||||
1 | 3 | MDP387 | Metrology | 3 | 5 | 125 | 2 | 0 | 3 | 5 | x | 15 | 25 | 15 | 40 | ( MDP281 ) | ||||
1 | 3 | MDP387s | Metrology | 3 | 5 | 125 | 2 | 0 | 3 | 5 | x | 20 | 25 | 15 | 40 | ( MDP281s ) | ||||
1 | 4 | MDP481 | Design of Tools & Production Facilities | 3 | 4 | 100 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | ( MDP382 ) | ||||
1 | 4 | MDP481s | Design of Tools & Production Facilities | 3 | 4 | 100 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP382s ) | ||||
1 | 4 | MDP482 | Metrology & Measuring Instruments | 4 | 8 | 200 | 3 | 0 | 5 | 8 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MDP482s | Metrology & Measuring Instruments | 4 | 8 | 200 | 3 | 0 | 5 | 8 | x | 20 | 25 | 15 | 40 | |||||
1 | 4 | MDP483 | Computerized Numerical Controlled Machines | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 15 | 25 | 10 | 40 | ( MDP382 ) | ||||
1 | 4 | MDP483s | Computerized Numerical Controlled Machines | 2 | 4 | 100 | 2 | 1 | 1 | 4 | x | 35 | 25 | 0 | 40 | ( MDP382s ) | ||||
1 | 4 | MDP484 | Product Life Cycle Management | 3 | 5 | 125 | 2 | 1 | 2 | 5 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MDP484s | Product Life Cycle Management | 3 | 5 | 125 | 2 | 1 | 2 | 5 | x | 35 | 25 | 0 | 40 | |||||
1 | 4 | MDP485 | Advanced Topics in CNC Machine Tools | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MDP483 ) | ||||
1 | 4 | MDP485s | Advanced Topics in CNC Machine Tools | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 60 | 0 | 0 | 40 | ( MDP483s ) | ||||
1 | 4 | MDP486 | Selected Topics in Manufacturing | 3 | 5 | 125 | 2 | 1 | 2 | 5 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MDP486s | Selected Topics in Manufacturing | 3 | 5 | 125 | 2 | 1 | 2 | 5 | x | 60 | 0 | 0 | 40 | |||||
1 | 4 | MDP487 | Computer Integrated Manufacturing | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 15 | 25 | 10 | 40 | ( MDP483 ) | ||||
1 | 4 | MDP487s | Computer Integrated Manufacturing | 3 | 5 | 125 | 2 | 2 | 1 | 5 | x | 35 | 25 | 0 | 40 | ( MDP483s ) | ||||
1 | 4 | MDP488 | Advanced Manufacturing Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MDP488s | Advanced Manufacturing Technology | 3 | 5 | 125 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | |||||
1 | 4 | MDP489 | Selected Topics in Forming | 3 | 5 | 125 | 2 | 1 | 2 | 5 | x | 15 | 25 | 10 | 40 | |||||
1 | 4 | MDP489s | Selected Topics in Forming | 3 | 5 | 125 | 2 | 1 | 2 | 5 | x | 60 | 0 | 0 | 40 | |||||
1 | 4 | MDP490 | Die Design | 3 | 6 | 150 | 2 | 3 | 0 | 5 | x | 30 | 25 | 0 | 40 | ( MDP281 ) AND ( MDP211 ) | ||||
1 | 4 | MDP490s | Die Design | 3 | 6 | 150 | 2 | 3 | 0 | 5 | x | 35 | 25 | 0 | 40 | ( MDP281s ) AND ( MDP211s ) | ||||
1 | 4 | MDP491 | Design of Jigs and Fixtures | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP211 ) AND ( MDP385 ) | ||||
1 | 4 | MDP491s | Design of Jigs and Fixtures | 2 | 6 | 150 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP211s ) AND ( MDP385s ) | ||||
1 | 4 | MDP492 | Advanced Manufacturing Systems | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 30 | 25 | 0 | 40 | ( MDP387 ) | ||||
1 | 4 | MDP492s | Advanced Manufacturing Systems | 3 | 6 | 150 | 2 | 2 | 1 | 5 | x | 35 | 25 | 0 | 40 | ( MDP387s ) | ||||
1 | 4 | MDP493 | Additive Manufacturing | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 30 | 25 | 0 | 40 | ( MDP462 ) | ||||
1 | 4 | MDP493s | Additive Manufacturing | 3 | 6 | 150 | 2 | 2 | 0 | 4 | x | 35 | 25 | 0 | 40 | ( MDP462s ) | ||||
1 | 4 | MDP494 | Advanced Manufacturing Technology & Prototyping | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 20 | 25 | 10 | 40 | ( MDP181 OR MDP183 ) | ||||
1 | 4 | MDP494s | Advanced Manufacturing Technology & Prototyping | 3 | 5 | 125 | 3 | 1 | 1 | 5 | x | 25 | 25 | 10 | 40 | ( MDP181s OR MDP183s ) |
MDP355 | Modern Iron and Steel Making | 2 CH | |||||||||
Prerequisites | ( MDP254 ) AND ( MDP256 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Types of Metals, History of metals making, Status of steel and nonferrous metal making in Egypt and world, Steel, Aluminium, copper, Magnesium and Titanium production and consumption, metals making fundamentals: Solution thermodynamics, Role of slag in steelmaking, properties of slag. Steel making fundamentals: Steelmaking reactions such as oxidation of carbon, silicon, manganese, iron, phosphorous and chromium, Numerical problems, Role of refractory. Steel making practice: Bessemer and open-hearth steel making, Blast furnace iron making, Basic oxygen steel making, Electric furnace steel making and vacuum treatment, ladle metallurgy, deoxidation and teeming practice, ingot production, ingot defects and remedies, testing of steel products, inspection of steel products. Clean steel, ingot and continuous casting, final finishing operations like heat treatment and deformation processing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP401 | Mechanical Design & Production Graduation Project (1) | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Identification of a real-life problem related to the program in general and the concentration in specific, Setting the overall objectives of the project and specific objectives of Project (1), Collecting data from the field, market and/or literature, Proposing engineering solutions, Developing conceptual ideas/designs, Conducting preliminary analyses, Comparing different ideas based on technical aspects, Selection of the solution approach. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
9 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 40% | 0% |
MDP401s | Mechanical Design & Production Graduation Project (1) | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Identification of a real-life problem related to the program in general and the concentration in specific, Setting the overall objectives of the project and specific objectives of Project (1), Collecting data from the field, market and/or literature, Proposing engineering solutions, Developing conceptual ideas/designs, Conducting preliminary analyses, Comparing different ideas based on technical aspects, Selection of the solution approach. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
50% | 0% | 0% | 50% |
MDP402 | Mechanical Design & Production Graduation Project (2) | 3 CH | |||||||||
Prerequisites | ( MDP401 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Setting the specific objectives of Project(2), Implementation of the solution(s) proposed in Project (1), Conducting necessary analyses, Developing necessary drawings, calculations, and models, Selecting appropriate materials, Using contemporary software tools, manufacturing of physical prototypes or physical models if necessary, testing and validation of the developed systems, Estimation of costs and necessary resources, Technical reporting of the project, Presenting the project activities and outcomes. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
10 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 40% | 0% |
MDP402s | Mechanical Design & Production Graduation Project (2) | 3 CH | |||||||||
Prerequisites | ( MDP401s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Setting the specific objectives of Project(2), Implementation of the solution(s) proposed in Project (1), Conducting necessary analyses, Developing necessary drawings, calculations, and models, Selecting appropriate materials, Using contemporary software tools, manufacturing of physical prototypes or physical models if necessary, testing and validation of the developed systems, Estimation of costs and necessary resources, Technical reporting of the project, Presenting the project activities and outcomes. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
50% | 0% | 0% | 50% |
MDP403 | Materials Engineering Graduation Project (1) | 3 CH | |||||||||
Prerequisites | ( MDP354 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Under supervision, the student should approach his graduation project within his Senior year. The purpose of this graduation project is to provide students with an opportunity to engage in an activity that will allow them to demonstrate their ability to apply the knowledge and skills they have gained throughout their years in the educational system. The project is designed to ensure that students are able to apply, analyse, synthesize, and evaluate information and to communicate significant knowledge and understanding. Problems/ topics to be considered should be materials engineering oriented, in any of the related disciplines offered by the faculty. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
5 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 40% | 0% |
MDP403s | Materials Engineering Graduation Project (1) | 3 CH | |||||||||
Prerequisites | ( MDP354s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Under supervision, the student should approach his graduation project within his Senior year. The purpose of this graduation project is to provide students with an opportunity to engage in an activity that will allow them to demonstrate their ability to apply the knowledge and skills they have gained throughout their years in the educational system. The project is designed to ensure that students are able to apply, analyse, synthesize, and evaluate information and to communicate significant knowledge and understanding. Problems/ topics to be considered should be materials engineering oriented, in any of the related disciplines offered by the faculty. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MDP404 | Materials Engineering Graduation Project (2) | 3 CH | |||||||||
Prerequisites | ( MDP403 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
This graduation project may be seen as a continuation of the first part (MDP 491: Graduation Project (1)) of a major topic, or it might be a new subject that the student is considering proving his competence in materials engineering practice. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
5 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 40% | 0% |
MDP404s | Materials Engineering Graduation Project (2) | 3 CH | |||||||||
Prerequisites | ( MDP403s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
This graduation project may be seen as a continuation of the first part (MDP 491: Graduation Project (1)) of a major topic, or it might be a new subject that the student is considering proving his competence in materials engineering practice. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MDP011 | Engineering Drawing | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 3 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Engineering drawing techniques and skills. Conventional lettering and dimensioning. Geometric constructions. Theories of view derivation. Orthographic projection of engineering bodies. Derivation of views from isometric drawings and vice versa. Derivation of views and sections from given views. Sectioning views: (half, removed, rotates, offset and partial sectioning). Introduction of assembly drawing. Computer aided drafting (CAD). | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
0 | 1 | |||||||||
Manufacturing Engineering |
0 | 1 | |||||||||
Mechatronics Engineering and Automation |
0 | 1 | |||||||||
Landscape Architecture |
0 | 1 | |||||||||
Environmental Architecture and Urbanism |
0 | 1 | |||||||||
Housing Architecture and Urban Development |
0 | 1 | |||||||||
Communication Systems Engineering |
0 | 1 | |||||||||
Energy and Renewable Energy Engineering |
0 | 1 | |||||||||
Computer Engineering and Software Systems |
0 | 1 | |||||||||
Building Engineering |
0 | 1 | |||||||||
Civil Infrastructure Engineering |
0 | 1 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 20% | 0% | 40% |
MDP011s | Engineering Drawing | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 3 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Engineering drawing techniques and skills. Conventional lettering and dimensioning. Geometric constructions. Theories of view derivation. Orthographic projection of engineering bodies. Derivation of views from isometric drawings and vice versa. Derivation of views and sections from given views. Sectioning views: (half, removed, rotates, offset and partial sectioning). Introduction of assembly drawing. Computer aided drafting (CAD). | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
1 | ||||||||||
Mechanical Power Engineering |
1 | ||||||||||
Automotive Engineering |
1 | ||||||||||
Mechatronics Engineering |
1 | ||||||||||
Architectural Engineering |
1 | ||||||||||
Electrical Power and Machines Engineering |
1 | ||||||||||
Electronics and Communications Engineering |
1 | ||||||||||
Computer and Systems Engineering |
1 | ||||||||||
Structural Engineering |
1 | ||||||||||
Water Engineering and Hydraulic Structures |
1 | ||||||||||
Utilities and Infrastructure |
1 | ||||||||||
Freshmen Level |
0 | ||||||||||
Freshmen Level |
1 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
40% | 20% | 0% | 40% |
MDP111 | Mechanical Engineering Drawing | 3 CH | |||||||||
Prerequisites | ( MDP011 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 3 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
In the tutorial these contents will be covered: Introduction to Machine parts and assembly drawing, Types of threaded fasteners and washers, Internal and external Thread Standards, definitions and drawings, Bearing drawings, types of fittings, Fits and Tolerances, Geometrical Tolerances, Surface Finish. Exercises on assembly drawings such as: crane hook, stuffing box, valves, grinding wheel drive, worm and worm gear, machine vice, hand press, transmission shaft, … etc. In the Lab. These contents will be covered: Introduction to solid modelling on a CAD software such as SolidWorks, Inventor, or any other CAD, Sketcher workbench, Solid work features: applied features, pattern features, fillets, design tables. 3D Modelling techniques;3D Part design, Parametric part design. 3D Assembly. 3D animation. Drafting and 2D drawings: basics, cross sections, dimensions, fits and tolerance. Sheet metal design; Weldment features. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
1 | 3 | |||||||||
Energy and Renewable Energy Engineering |
1 | 4 | |||||||||
Materials Engineering |
1 | 3 | |||||||||
Mechatronics Engineering and Automation |
1 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP111s | Mechanical Engineering Drawing | 3 CH | |||||||||
Prerequisites | ( MDP011s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 3 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
In the tutorial these contents will be covered: Introduction to Machine parts and assembly drawing, Types of threaded fasteners and washers, Internal and external Thread Standards, definitions and drawings, Bearing drawings, types of fittings, Fits and Tolerances, Geometrical Tolerances, Surface Finish. Exercises on assembly drawings such as: crane hook, stuffing box, valves, grinding wheel drive, worm and worm gear, machine vice, hand press, transmission shaft, … etc. In the Lab. These contents will be covered: Introduction to solid modelling on a CAD software such as SolidWorks, Inventor, or any other CAD, Sketcher workbench, Solid work features: applied features, pattern features, fillets, design tables. 3D Modelling techniques;3D Part design, Parametric part design. 3D Assembly. 3D animation. Drafting and 2D drawings: basics, cross sections, dimensions, fits and tolerance. Sheet metal design; Weldment features. | |||||||||||
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 | ||||||||
20% | 25% | 15% | 40% |
MDP112 | Machine Construction | 3 CH | |||||||||
Prerequisites | ( MDP111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Loading Diagrams, General concepts of Stress and Strain, Types of Stresses (Normal Stresses and Shear Stresses), Combined Stresses, Theories of Elastic Failure, Safety Factor. Constructional details as affected by manufacturing, assembly, and strength considerations, Connections (Centring, Flanged, Riveted, Keyed, Splined, Screwed), Power Screw and its joints, Seals, Springs, Stress Concentrations, Reverse Engineering. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
2 | 5 | |||||||||
Materials Engineering |
2 | 5 | |||||||||
Mechatronics Engineering and Automation |
2 | 5 | |||||||||
Energy and Renewable Energy Engineering |
2 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MDP112s | Machine Construction | 3 CH | |||||||||
Prerequisites | ( MDP111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Loading Diagrams, General concepts of Stress and Strain, Types of Stresses (Normal Stresses and Shear Stresses), Combined Stresses, Theories of Elastic Failure, Safety Factor. Constructional details as affected by manufacturing, assembly, and strength considerations, Connections (Centring, Flanged, Riveted, Keyed, Splined, Screwed), Power Screw and its joints, Seals, Springs, Stress Concentrations, Reverse Engineering. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
2 | 1 | |||||||||
Automotive Engineering |
2 | ||||||||||
Mechanical Power Engineering |
2 | 1 | |||||||||
Mechatronics Engineering |
2 | ||||||||||
General Mechanical Engineering |
2 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 0% | 50% |
MDP211 | Machine Elements Design | 4 CH | |||||||||
Prerequisites | ( MDP112 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Introduction to Design Concepts, General Concepts of (Deflection, Buckling and Thermal Stresses), Design for Fatigue, Design of Machine Elements (Bolts, Power Screws, Rivets, Keys, Welded Joints, Springs), Design of Power Transmission Elements (Shafts, Couplings, Gears, Belt Drives, Chain Drives), Selection of Bearings, Design of Pressure Cylinders. Use of interactive Finite Element computer programs for problem solving is illustrated and used. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
2 | 6 | |||||||||
Energy and Renewable Energy Engineering |
3 | 8 | |||||||||
Mechatronics Engineering and Automation |
2 | 6 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 20% | 0% | 40% |
MDP211s | Machine Elements Design | 4 CH | |||||||||
Prerequisites | ( MDP112s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Introduction to Design Concepts, General Concepts of (Deflection, Buckling and Thermal Stresses), Design for Fatigue, Design of Machine Elements (Bolts, Power Screws, Rivets, Keys, Welded Joints, Springs), Design of Power Transmission Elements (Shafts, Couplings, Gears, Belt Drives, Chain Drives), Selection of Bearings, Design of Pressure Cylinders. Use of interactive Finite Element computer programs for problem solving is illustrated and used. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
2 | ||||||||||
Design and Production Engineering |
2 | 5 | |||||||||
Mechanical Power Engineering |
2 | 5 | |||||||||
Automotive Engineering |
2 | 5 | |||||||||
Mechatronics Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
40% | 20% | 0% | 40% |
MDP212 | Mechanics of Machines | 4 CH | |||||||||
Prerequisites | ( PHM131 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 3 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Mechanisms: Definitions, open-chain systems, closed-chain systems constraints, degrees of freedom, reference frames, inversions of four linkage (lower pair) mechanisms, slotted lever mechanism, steering mechanisms, inversions of mechanisms, Hook’s joint, and synthesis of mechanisms. Kinematics: Kinematics of rigid bodies, position analysis, velocity analysis, acceleration analysis, rotation representations, Euler angles, rotation matrix, homogeneous transformation matrix, direct and inverse kinematics. Dynamics: Equilibrium of machines, D’Alembert’s principle, force analysis, power analysis, Friction and inertia-effects, centre of percussion, flywheel design. Kinetics of single degree of freedom mechanisms: Free body diagrams, Static equilibrium, Equation of motion. Cams: Types of cams, types of followers, kinematics and kinetics of cam. Gears: Concept of gear motion transmission, gear geometry and gear trains. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
1 | 4 | |||||||||
Mechatronics Engineering and Automation |
1 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 15% | 10% | 40% |
MDP212s | Mechanics of Machines | 4 CH | |||||||||
Prerequisites | ( PHM131s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 3 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Mechanisms: Definitions, open-chain systems, closed-chain systems constraints, degrees of freedom, reference frames, inversions of four linkage (lower pair) mechanisms, slotted lever mechanism, steering mechanisms, inversions of mechanisms, Hook’s joint, and synthesis of mechanisms. Kinematics: Kinematics of rigid bodies, position analysis, velocity analysis, acceleration analysis, rotation representations, Euler angles, rotation matrix, homogeneous transformation matrix, direct and inverse kinematics. Dynamics: Equilibrium of machines, D’Alembert’s principle, force analysis, power analysis, Friction and inertia-effects, centre of percussion, flywheel design. Kinetics of single degree of freedom mechanisms: Free body diagrams, Static equilibrium, Equation of motion. Cams: Types of cams, types of followers, kinematics and kinetics of cam. Gears: Concept of gear motion transmission, gear geometry and gear trains. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
2 | ||||||||||
Design and Production Engineering |
2 | 5 | |||||||||
Mechanical Power Engineering |
2 | 5 | |||||||||
Automotive Engineering |
2 | 5 | |||||||||
Mechatronics Engineering |
2 | 5 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 15% | 0% | 60% |
MDP311 | Mechanical Vibrations | 4 CH | |||||||||
Prerequisites | ( PHM131 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Introduction, Vibration of single degree of freedom systems (free, damped, forced), Vibration isolation, Vibration of two degree of freedom systems (free, forced), Vibration absorber, Torsional vibrations (free, forced), Equivalent torsional systems: Geared system, Crank system, Multi-degree-of-freedom systems, Continuous systems: bending of shafts, analytical solution, balancing of rotary mass, Whirling of shafts, Vibration measurements. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP311s | Mechanical Vibrations | 4 CH | |||||||||
Prerequisites | ( PHM131s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Introduction, Vibration of single degree of freedom systems (free, damped, forced), Vibration isolation, Vibration of two degree of freedom systems (free, forced), Vibration absorber, Torsional vibrations (free, forced), Equivalent torsional systems: Geared system, Crank system, Multi-degree-of-freedom systems, Continuous systems: bending of shafts, analytical solution, balancing of rotary mass, Whirling of shafts, Vibration measurements. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
3 | ||||||||||
Design and Production Engineering |
3 | 6 | |||||||||
Mechanical Power Engineering |
3 | 6 | |||||||||
Automotive Engineering |
3 | 6 | |||||||||
Mechatronics Engineering |
3 | 6 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 15% | 0% | 60% |
MDP312 | Mechanical System Design | 3 CH | |||||||||
Prerequisites | ( MDP211 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Project work (mainly an industrial problem with focus on detail design in a system context). Innovation, creativity and patent. Information sources and search, benchmarking. The product development process, project planning. Requirement specification, QFD. Concept development, functions-means tree, concept selection. Detail design, considering environmental effects, material selection, ergonomics. Solid mechanics for modelling and dimensioning (both using FEM and analytical). Manufacturing documents (detail drawings including manufacturing tolerances). Assembling, testing, evaluation, redesign. Presentation and communication, both orally and in different form of written documentation. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP312s | Mechanical System Design | 3 CH | |||||||||
Prerequisites | ( MDP211s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Project work (mainly an industrial problem with focus on detail design in a system context). Innovation, creativity and patent. Information sources and search, benchmarking. The product development process, project planning. Requirement specification, QFD. Concept development, functions-means tree, concept selection. Detail design, considering environmental effects, material selection, ergonomics. Solid mechanics for modelling and dimensioning (both using FEM and analytical). Manufacturing documents (detail drawings including manufacturing tolerances). Assembling, testing, evaluation, redesign. Presentation and communication, both orally and in different form of written documentation. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MDP411 | Introduction to Finite Elements | 3 CH | |||||||||
Prerequisites | ( PHM112 ) AND ( MDP112 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Overview and Introduction to Variational Methods, Bar Problem, Truss problem, Two-dimensional plate problem: Plane stress, Plane strain, Numerical integration, Beam bending problem, Buckling of beams, MATLAB programming of all problems, FE Applications Using Software Packages, Eigenvalue Problems (Structural Dynamics/Buckling of Beams) | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
45% | 20% | 0% | 30% |
MDP411s | Introduction to Finite Elements | 3 CH | |||||||||
Prerequisites | ( PHM112s ) AND ( MDP112s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Overview and Introduction to Variational Methods, Bar Problem, Truss problem, Two-dimensional plate problem: Plane stress, Plane strain, Numerical integration, Beam bending problem, Buckling of beams, MATLAB programming of all problems, FE Applications Using Software Packages, Eigenvalue Problems (Structural Dynamics/Buckling of Beams) | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 8 | |||||||||
Mechatronics Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
50% | 20% | 0% | 30% |
MDP412 | Noise & Vibration Control | 3 CH | |||||||||
Prerequisites | ( MDP312 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction, fields of application, effect of sound and vibration on man and equipment. Fundamental Concepts, Signal Analysis and Measurement Techniques, Vibrations of simple mechanical systems, Continuous systems in 1D, and mode shapes, Introduction to 2-dimensional systems, Building Acoustics and sound propagation outdoors, Sound in Ducts and Flow induced vibrations, Principles of noise and vibration control, Study of the sound and vibration of selected machines, Standards and Regulations. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP412s | Noise & Vibration Control | 3 CH | |||||||||
Prerequisites | ( MDP312s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction, fields of application, effect of sound and vibration on man and equipment. Fundamental Concepts, Signal Analysis and Measurement Techniques, Vibrations of simple mechanical systems, Continuous systems in 1D, and mode shapes, Introduction to 2-dimensional systems, Building Acoustics and sound propagation outdoors, Sound in Ducts and Flow induced vibrations, Principles of noise and vibration control, Study of the sound and vibration of selected machines, Standards and Regulations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
|||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 20% | 0% | 60% |
MDP413 | Design Optimization | 3 CH | |||||||||
Prerequisites | ( PHM112 ) AND ( MDP211 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Principles of optimization in design process, design variables, objective functions, constraints, optimization problem formulation, optimality criteria and conditions, single-variable optimization, graphical optimization, multivariable optimization without constraints and with constraints, Linear, quadratic, nonlinear and dynamic programming optimization problems. Evolutionary design algorithms for global optimization such as genetic algorithm. Structural Optimization: size optimization, Shape optimization, Topology optimization. Automated design optimization and design exploration. All design optimization examples in this course will be on mechanical structures and machine elements such as cantilevers, beams, coil springs, shafts, pressure vessels, bars, trusses, cross section shapes ...etc. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP413s | Design Optimization | 3 CH | |||||||||
Prerequisites | ( PHM112s ) AND ( MDP211s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Principles of optimization in design process, design variables, objective functions, constraints, optimization problem formulation, optimality criteria and conditions, single-variable optimization, graphical optimization, multivariable optimization without constraints and with constraints, Linear, quadratic, nonlinear and dynamic programming optimization problems. Evolutionary design algorithms for global optimization such as genetic algorithm. Structural Optimization: size optimization, Shape optimization, Topology optimization. Automated design optimization and design exploration. All design optimization examples in this course will be on mechanical structures and machine elements such as cantilevers, beams, coil springs, shafts, pressure vessels, bars, trusses, cross section shapes ...etc. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 20% | 20% | 40% |
MDP414 | Product Design & Development | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Design Methodologies, Product Development Process, Task Clarification, Generic Design Process (Conceptual, Embodiment, Detail, Robust, Modular, System), Design for X, DFM, DFA, DFMA, Product Design and Development – Case Studies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 20% | 0% | 40% |
MDP414s | Product Design & Development | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Design Methodologies, Product Development Process, Task Clarification, Generic Design Process (Conceptual, Embodiment, Detail, Robust, Modular, System), Design for X, DFM, DFA, DFMA, Product Design and Development – Case Studies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
40% | 20% | 0% | 40% |
MDP415 | Selected Topics in Mechanical Design | 3 CH | |||||||||
Prerequisites | ( MDP312 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Contemporary topics in mechanical design, Multi-objective design, Design for X, Design optimization, Innovation in mechanical design, software and hardware tools for mechanical design, Design standardization, etc. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP415s | Selected Topics in Mechanical Design | 3 CH | |||||||||
Prerequisites | ( MDP312s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Contemporary topics in mechanical design, Multi-objective design, Design for X, Design optimization, Innovation in mechanical design, software and hardware tools for mechanical design, Design standardization, etc. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
40% | 20% | 0% | 40% |
MDP231 | Engineering Economy | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Origins of engineering economy, Principles of engineering economy, Design and manufacturing processes and EE, Cost estimation and cost terminology, Accounting, Balance sheet, Profit loss statement, Concept of equivalence, Money time relationships, Simple and compound interest rates, Single amounts and uniform series, Increasing and decreasing gradient, Application of money, Time relationships, Present value, Internal rate of return, External rate of return, Payback period, Evaluation of alternatives for different useful life and study period, Depreciation methods, Replacement analysis, Determination of the economic life of challenger and defender, Engineering economy techniques for evaluation of public projects. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | 5 | |||||||||
Mechatronics Engineering and Automation |
3 | 6 | |||||||||
Materials Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP231s | Engineering Economy | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Origins of engineering economy, Principles of engineering economy, Design and manufacturing processes and EE, Cost estimation and cost terminology, Accounting, Balance sheet, Profit loss statement, Concept of equivalence, Money time relationships, Simple and compound interest rates, Single amounts and uniform series, Increasing and decreasing gradient, Application of money, Time relationships, Present value, Internal rate of return, External rate of return, Payback period, Evaluation of alternatives for different useful life and study period, Depreciation methods, Replacement analysis, Determination of the economic life of challenger and defender, Engineering economy techniques for evaluation of public projects. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
2 | 5 | |||||||||
Mechanical Power Engineering |
2 | 5 | |||||||||
Automotive Engineering |
4 | 10 | |||||||||
Mechatronics Engineering |
2 | 6 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP232 | Industrial Project Management | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Definitions used in project management, The project life cycle, Project stages, Relationships and responsibilities of the different project parties, Work Breakdown Structure (WBS) and Linear Responsibility Chart (LRC), Project Scheduling, Network planning: Activity on arrow, Activity on node, CPM, PERT, Progress monitoring, Project crashing, Progress curves, Resource allocation and levelling. Project productivity, Quality management. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | 7 | |||||||||
Materials Engineering |
3 | 6 | |||||||||
Mechatronics Engineering and Automation |
2 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP232s | Industrial Project Management | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Definitions used in project management, The project life cycle, Project stages, Relationships and responsibilities of the different project parties, Work Breakdown Structure (WBS) and Linear Responsibility Chart (LRC), Project Scheduling, Network planning: Activity on arrow, Activity on node, CPM, PERT, Progress monitoring, Project crashing, Progress curves, Resource allocation and levelling. Project productivity, Quality management. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 6 | |||||||||
Mechanical Power Engineering |
3 | 6 | |||||||||
Automotive Engineering |
4 | 8 | |||||||||
Mechatronics Engineering |
3 | 6 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP233 | Work Study and Plant Layout | 4 CH | |||||||||
Prerequisites | ( PHM111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Productivity: Factors affecting productivity and role of management, Introduction to work study: Objectives, Techniques applied, Method study techniques: Charts and diagrams, Critical examination and analysis, Developing new methods, Measures and controls, Work measurements: Direct and indirect methods, Relaxation allowances and calculation of standard time, Learning curves: Concept, Application in work study and determination of standard time, workers incentives. Plant layout objectives and requirement, Work station layout, SLP, Setting the Layout. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP233s | Work Study and Plant Layout | 4 CH | |||||||||
Prerequisites | ( PHM111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Productivity: Factors affecting productivity and role of management, Introduction to work study: Objectives, Techniques applied, Method study techniques: Charts and diagrams, Critical examination and analysis, Developing new methods, Measures and controls, Work measurements: Direct and indirect methods, Relaxation allowances and calculation of standard time, Learning curves: Concept, Application in work study and determination of standard time, workers incentives. Plant layout objectives and requirement, Work station layout, SLP, Setting the Layout. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP331 | Maintenance Planning and Scheduling | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Introduction and concepts in maintenance management, Maintenance organization, Types of maintenances: preventive, predictive, programmed, emergency, repair, etc. Maintenance planning and scheduling, spare parts management and control. Total Productive Maintenance (TPM), maintenance information system, maintenance cost, maintenance safety. Different approaches to evaluate Overall Equipment Effectiveness (OEE) and understanding Six Major Equipment Losses. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP331s | Maintenance Planning and Scheduling | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Introduction and concepts in maintenance management, Maintenance organization, Types of maintenances: preventive, predictive, programmed, emergency, repair, etc. Maintenance planning and scheduling, spare parts management and control. Total Productive Maintenance (TPM), maintenance information system, maintenance cost, maintenance safety. Different approaches to evaluate Overall Equipment Effectiveness (OEE) and understanding Six Major Equipment Losses. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
3 | ||||||||||
Design and Production Engineering |
3 | ||||||||||
Mechanical Power Engineering |
3 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP332 | Work Study | 3 CH | |||||||||
Prerequisites | ( PHM111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Productivity: Factors affecting productivity and role of management, Introduction to work study: Objectives, Techniques applied, Method study techniques: Charts and diagrams, Critical examination and analysis, Developing new methods, Measures and controls, Work measurements: Direct and indirect methods, Relaxation allowances and calculation of standard time, Learning curves: Concept, Application in work study and determination of standard time, workers incentives | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP332s | Work Study | 3 CH | |||||||||
Prerequisites | ( PHM111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Productivity: Factors affecting productivity and role of management, Introduction to work study: Objectives, Techniques applied, Method study techniques: Charts and diagrams, Critical examination and analysis, Developing new methods, Measures and controls, Work measurements: Direct and indirect methods, Relaxation allowances and calculation of standard time, Learning curves: Concept, Application in work study and determination of standard time, workers incentives | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP333 | Operations Research | 3 CH | |||||||||
Prerequisites | ( PHM013 ) AND ( PHM111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Linear programming: Formulation, Graphical solution, Simplex method, and Duality and sensitivity analysis, Transportation models: Transportation algorithm, Assignment problem and transshipment problem, Network models: Minimal spanning tree algorithm, Shortest route problem and Maximum flow problem, Branch and bound algorithm, | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP333s | Operations Research | 3 CH | |||||||||
Prerequisites | ( PHM013s ) AND ( PHM111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Linear programming: Formulation, Graphical solution, Simplex method, and Duality and sensitivity analysis, Transportation models: Transportation algorithm, Assignment problem and transshipment problem, Network models: Minimal spanning tree algorithm, Shortest route problem and Maximum flow problem, Branch and bound algorithm, | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP334 | Principles of Operations Management | 3 CH | |||||||||
Prerequisites | ( MDP331 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Competitiveness, Strategy and Productivity, Forecasting and time series analysis (qualitative techniques: Sales force polling, Customers’ opinion, Delphi technique, Quantitative techniques: Smoothing methods, Averaging Methods, Linear regression), Product and service design, Capacity planning (defining capacity, rough-cut capacity planning, detailed capacity planning), Aggregate production planning, | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP334s | Principles of Operations Management | 3 CH | |||||||||
Prerequisites | ( MDP331s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Competitiveness, Strategy and Productivity, Forecasting and time series analysis (qualitative techniques: Sales force polling, Customers’ opinion, Delphi technique, Quantitative techniques: Smoothing methods, Averaging Methods, Linear regression), Product and service design, Capacity planning (defining capacity, rough-cut capacity planning, detailed capacity planning), Aggregate production planning, | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP335 | Production Planning and Scheduling | 3 CH | |||||||||
Prerequisites | ( MDP334 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Inventory management and control (determining optimal order quantity, optimal production quantity, safety stock), Materials requirement planning, Enterprise resources planning, Production scheduling and sequencing, Assembly line balancing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP335s | Production Planning and Scheduling | 3 CH | |||||||||
Prerequisites | ( MDP334s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Inventory management and control (determining optimal order quantity, optimal production quantity, safety stock), Materials requirement planning, Enterprise resources planning, Production scheduling and sequencing, Assembly line balancing. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP336 | Facilities Layout and Design | 3 CH | |||||||||
Prerequisites | ( MDP233 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to production systems, Types and characteristics of production systems, Product and Process design, Quantitative and qualitative data, Number of machines and manpower, Quantitative and qualitative techniques for construction of initial layout, improvement layout techniques, Computerized layout techniques, Single facility location problem, Assembly line balancing, Warehouse design, Introduction to materials handling equipment and systems, Setting the facility plan, Lighting and environmental considerations, factories utilities, office layout and labour services. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP336s | Facilities Layout and Design | 3 CH | |||||||||
Prerequisites | ( MDP233s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to production systems, Types and characteristics of production systems, Product and Process design, Quantitative and qualitative data, Number of machines and manpower, Quantitative and qualitative techniques for construction of initial layout, improvement layout techniques, Computerized layout techniques, Single facility location problem, Assembly line balancing, Warehouse design, Introduction to materials handling equipment and systems, Setting the facility plan, Lighting and environmental considerations, factories utilities, office layout and labour services. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP431 | Operations Management | 3 CH | |||||||||
Prerequisites | ( MDP231 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Forecasting and time series analysis (qualitative techniques: Sales force polling,, Customers’ opinion, Delphi technique, Quantitative techniques: Smoothing methods, Averaging Methods, Linear regression), Capacity planning(defining capacity, rough-cut capacity planning, detailed capacity planning), Aggregate production planning, Inventory management and control (determining optimal order quantity, optimal production quantity, safety stock), Materials requirement planning, Work loading and scheduling. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP431s | Operations Management | 3 CH | |||||||||
Prerequisites | ( MDP231s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Forecasting and time series analysis (qualitative techniques: Sales force polling,, Customers’ opinion, Delphi technique, Quantitative techniques: Smoothing methods, Averaging Methods, Linear regression), Capacity planning(defining capacity, rough-cut capacity planning, detailed capacity planning), Aggregate production planning, Inventory management and control (determining optimal order quantity, optimal production quantity, safety stock), Materials requirement planning, Work loading and scheduling. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP432 | Facilities Planning | 3 CH | |||||||||
Prerequisites | ( MDP332 ) AND ( MDP333 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Introduction to production systems, Types and characteristics of production systems, Types of layouts, Advantages and disadvantages of each, Layout objectives, Types of layout data, Quantitative and qualitative data, Construction of flow matrix, Construction of activity relationship chart, Space determination, Number of machines and manpower, Quantitative and qualitative techniques for construction of initial layout, improvement layout techniques, Computerized layout techniques, Evaluation of solutions and selection of the optimum, Single facility location problem, Introduction to materials handling equipment and systems | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP432s | Facilities Planning | 3 CH | |||||||||
Prerequisites | ( MDP332s ) AND ( MDP333s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Introduction to production systems, Types and characteristics of production systems, Types of layouts, Advantages and disadvantages of each, Layout objectives, Types of layout data, Quantitative and qualitative data, Construction of flow matrix, Construction of activity relationship chart, Space determination, Number of machines and manpower, Quantitative and qualitative techniques for construction of initial layout, improvement layout techniques, Computerized layout techniques, Evaluation of solutions and selection of the optimum, Single facility location problem, Introduction to materials handling equipment and systems | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP433 | Quality Control | 3 CH | |||||||||
Prerequisites | ( PHM111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
History of quality control Quality definitions and concepts, Process capability analysis, Theory of control charts, Statistical control charts for attributes, Statistical control charts for variables, Acceptance sampling: Principles and concepts, Acceptance sampling by attributes, Acceptance sampling by variables. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | 7 | |||||||||
Manufacturing Engineering |
5 | 10 | |||||||||
Energy and Renewable Energy Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP433s | Quality Control | 3 CH | |||||||||
Prerequisites | ( PHM111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
History of quality control Quality definitions and concepts, Process capability analysis, Theory of control charts, Statistical control charts for attributes, Statistical control charts for variables, Acceptance sampling: Principles and concepts, Acceptance sampling by attributes, Acceptance sampling by variables. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
5 | 10 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP434 | Quality Systems & Assurance | 3 CH | |||||||||
Prerequisites | ( PHM111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Basic concepts, Definitions, Terminology, Development of quality control systems Quality systems for: design, development, purchasing, and Planning, Quality organization, Cost of quality, Economics of quality, Training, Quality Management Systems, Quality assurance, Employee participation programs. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP434s | Quality Systems & Assurance | 3 CH | |||||||||
Prerequisites | ( PHM111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Basic concepts, Definitions, Terminology, Development of quality control systems Quality systems for: design, development, purchasing, and Planning, Quality organization, Cost of quality, Economics of quality, Training, Quality Management Systems, Quality assurance, Employee participation programs. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP435 | Industrial Systems Modeling & Simulation | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to industrial systems modelling, Basic simulation models, modelling complex systems, Discrete event simulation, hand simulation, Simulation software, Building simulation models, Output data analysis for a single system, Comparing alternative system configurations, Variance reduction techniques, Sensitivity analysis, Simulation of manufacturing systems. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP435s | Industrial Systems Modeling & Simulation | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to industrial systems modelling, Basic simulation models, modelling complex systems, Discrete event simulation, hand simulation, Simulation software, Building simulation models, Output data analysis for a single system, Comparing alternative system configurations, Variance reduction techniques, Sensitivity analysis, Simulation of manufacturing systems. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
50% | 0% | 50% | 0% |
MDP436 | Production Planning & Control | 3 CH | |||||||||
Prerequisites | ( MDP431 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Operations strategy in global economy; strategic management inputs; strategic actions (strategy formulation and implementation); product process and service design; operations technologies; strategic allocation of resources; supply chain management; decision making and planning with uncertainty; cost management; enterprise resource planning; lean synchronization; operations improvement; risk management. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP436s | Production Planning & Control | 3 CH | |||||||||
Prerequisites | ( MDP431s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Operations strategy in global economy; strategic management inputs; strategic actions (strategy formulation and implementation); product process and service design; operations technologies; strategic allocation of resources; supply chain management; decision making and planning with uncertainty; cost management; enterprise resource planning; lean synchronization; operations improvement; risk management. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP437 | Ergonomics | 3 CH | |||||||||
Prerequisites | ( MDP332 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
A Systematic approach to the optimization of the human task environment system: Workspace design, Manual materials handling, Cumulative trauma disorders and environmental factors, Emphasis on industrial applications, Ergonomics process, Anatomy, Anthropometry, Workplace design, Hand use design, Office ergonomics, Handling loads, Work physiology, Design for special populations, Information processing, Noise, Vibration, illumination, Control and display design. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP437s | Ergonomics | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
A Systematic approach to the optimization of the human task environment system: Workspace design, Manual materials handling, Cumulative trauma disorders and environmental factors, Emphasis on industrial applications, Ergonomics process, Anatomy, Anthropometry, Workplace design, Hand use design, Office ergonomics, Handling loads, Work physiology, Design for special populations, Information processing, Noise, Vibration, illumination, Control and display design. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP438 | Simulation of Manufacturing Systems | 3 CH | |||||||||
Prerequisites | ( MDP332 OR MDP233 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to industrial systems modelling, Basic simulation models, modelling complex systems, hand simulation, Discrete event simulation, Simulation software, Building simulation models, Output data analysis for a single system, Comparing alternative system configurations, Simulation of manufacturing systems. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP438s | Simulation of Manufacturing Systems | 3 CH | |||||||||
Prerequisites | ( MDP332s OR MDP233s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to industrial systems modelling, Basic simulation models, modelling complex systems, hand simulation, Discrete event simulation, Simulation software, Building simulation models, Output data analysis for a single system, Comparing alternative system configurations, Simulation of manufacturing systems. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP439 | Lean Manufacturing Systems | 3 CH | |||||||||
Prerequisites | ( MPD334 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Fundamentals of lean manufacturing principles. Toyota house, seven wastes, Push verse Pull systems and JIT, Kanban system, Kanban size and number, CONWIP. Value stream mapping: How to construct the current state map, improvement tools Kaizen, Poka-a-Yoke, 5S. Takt time calculations and production levelling. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | 8 | |||||||||
Manufacturing Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP439s | Lean Manufacturing Systems | 3 CH | |||||||||
Prerequisites | ( MPD334s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Fundamentals of lean manufacturing principles. Toyota house, seven wastes, Push verse Pull systems and JIT, Kanban system, Kanban size and number, CONWIP. Value stream mapping: How to construct the current state map, improvement tools Kaizen, Poka-a-Yoke, 5S. Takt time calculations and production levelling. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP440 | Quality Assurance and Six Sigma | 3 CH | |||||||||
Prerequisites | ( PHM111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Quality control systems, Quality systems for: design, development, purchasing, and Planning, Quality organization, Cost of quality, Training, Quality Management Systems, Quality assurance, ISO 9000 principles, other certification (CE mark, OSHA, … etc.), Employee participation programs. Six Sigma principles, Six Sigma as tool for development. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP440s | Quality Assurance and Six Sigma | 3 CH | |||||||||
Prerequisites | ( PHM111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Quality control systems, Quality systems for: design, development, purchasing, and Planning, Quality organization, Cost of quality, Training, Quality Management Systems, Quality assurance, ISO 9000 principles, other certification (CE mark, OSHA, … etc.), Employee participation programs. Six Sigma principles, Six Sigma as tool for development. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP441 | Industrial Technologies | 2 CH | |||||||||
Prerequisites | ( MDP233 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Primary, secondary tertiary and Quaternary economies and their relation to manufacturing activities. Different types of industries and technologies used in various industries such as food industries, apparel industries, building materials industries, petrochemical industries. A focus will be made on the different equipment, characteristics and considerations related to each industry. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
45% | 10% | 0% | 40% |
MDP441s | Industrial Technologies | 2 CH | |||||||||
Prerequisites | ( MDP233s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Primary, secondary tertiary and Quaternary economies and their relation to manufacturing activities. Different types of industries and technologies used in various industries such as food industries, apparel industries, building materials industries, petrochemical industries. A focus will be made on the different equipment, characteristics and considerations related to each industry. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
50% | 10% | 0% | 40% |
MDP151 | Structures & Properties of Materials | 2 CH | |||||||||
Prerequisites | ( PHM041 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Engineering materials: metals, polymers, ceramics, and composites. The internal structure of material: atomic structure, atomic arrangement, microstructure, and macrostructure. Good exploitation of the material requirements for a set of properties suitable for this use. Material properties: physical, chemical, mechanical, electrical, thermal, and optical properties. Relationship between material properties and its internal structure, method of synthesizing, manufacturing, processing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
2 | 3 | |||||||||
Manufacturing Engineering |
2 | 3 | |||||||||
Mechatronics Engineering and Automation |
2 | 3 | |||||||||
Energy and Renewable Energy Engineering |
2 | 3 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP151s | Structures & Properties of Materials | 2 CH | |||||||||
Prerequisites | ( PHM041s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Engineering materials: metals, polymers, ceramics, and composites. The internal structure of material: atomic structure, atomic arrangement, microstructure, and macrostructure. Good exploitation of the material requirements for a set of properties suitable for this use. Material properties: physical, chemical, mechanical, electrical, thermal, and optical properties. Relationship between material properties and its internal structure, method of synthesizing, manufacturing, processing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
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 | ||||||||
25% | 25% | 10% | 40% |
MDP152 | Metallurgy & Material Testing | 3 CH | |||||||||
Prerequisites | ( MDP151 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
This course provides a general treatment of the principles and problems of engineering materials and testing with specific reference to mechanical properties. It also covers the common methods of static and dynamic testing: tension, compression, bending, shear, hardness, impact, creep, and fatigue. Other topics are also included namely the types of fracture and the non-destructive testing of materials. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
2 | 4 | |||||||||
Manufacturing Engineering |
1 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 20% | 20% | 40% |
MDP152s | Metallurgy & Material Testing | 3 CH | |||||||||
Prerequisites | ( MDP151s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
This course provides a general treatment of the principles and problems of engineering materials and testing with specific reference to the mechanical properties. It also covers the common methods of static and dynamic testing: tension, compression, bending, shear, hardness, impact, creep and fatigue. Other topics are also included namely the types of fracture and the non-destructive testing of materials. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
2 | ||||||||||
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 | ||||||||
10% | 10% | 20% | 60% |
MDP153 | Crystalline Structures of Materials | 3 CH | |||||||||
Prerequisites | ( MDP151 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Solidification processes, nucleation, crystal growth, crystal geometry, physical properties of crystals, Miller indices, x-ray diffraction methods for the determination of crystalline structures and chemical compositions, electron and neutron diffraction methods, crystalline defects, dislocations, crystal and phase boundaries, precipitation and segregation, revision of Gibbs free energy rules, cooling curves, phase diagrams, phase transitions, tertiary phase diagrams. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
1 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP153s | Crystalline Structures of Materials | 3 CH | |||||||||
Prerequisites | ( MDP151s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Solidification processes, nucleation, crystal growth, crystal geometry, physical properties of crystals, Miller indices, x-ray diffraction methods for the determination of crystalline structures and chemical compositions, electron and neutron diffraction methods, crystalline defects, dislocations, crystal and phase boundaries, precipitation and segregation, revision of Gibbs free energy rules, cooling curves, phase diagrams, phase transitions, tertiary phase diagrams. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |
MDP251 | Casting & Welding (1) | 3 CH | |||||||||
Prerequisites | ( MDP152 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Metal casting technology: Introduction, Solidification processing, Liquid metals, Principles of solidification, Primary (wrought) and casting, Metals and alloys, Production of primary metals, Production of shaped casting, Patterns, Moulding techniques: Moulding techniques and dynamics, Melting procedures and equipment, Design considerations, Structure, Properties and defects of casting, Casting process selection, Computer applications in metal casting, Quality control in casting, advanced casting processes. Metal Welding Definition, Welding Joints, Welding Standards, Welding Symbols, Fusion Welding Processes, Solid State Welding Processes, High Energy Welding Processes, Heat Flow in Metal Welding, Chemical Reactions and Fluid Flow in Arc Welding, Solidification of Fusion Zone, Weldability and Cracking Susceptibility, Welding Defects, and Inspection of Welded Joints. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
2 | 5 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 10% | 10% | 40% |
MDP251s | Casting & Welding (1) | 3 CH | |||||||||
Prerequisites | ( MDP152s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Metal casting technology: Introduction, Solidification processing, Liquid metals, Principles of solidification, Primary (wrought) and casting, Metals and alloys, Production of primary metals, Production of shaped casting, Patterns, Moulding techniques: Moulding techniques and dynamics, Melting procedures and equipment, Design considerations, Structure, Properties and defects of casting, Casting process selection, Computer applications in metal casting, Quality control in casting, advanced casting processes. Metal Welding Definition, Welding Joints, Welding Standards, Welding Symbols, Fusion Welding Processes, Solid State Welding Processes, High Energy Welding Processes, Heat Flow in Metal Welding, Chemical Reactions and Fluid Flow in Arc Welding, Solidification of Fusion Zone, Weldability and Cracking Susceptibility, Welding Defects, and Inspection of Welded Joints. | |||||||||||
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 |
5 | ||||||||||
Mechatronics Engineering |
6 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 10% | 10% | 60% |
MDP252 | Casting & Welding (2) | 2 CH | |||||||||
Prerequisites | ( MDP251 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Casting techniques: die casting, continuous casting, centrifugal casting, ribbon casting, rheocasting, investment casting, casting defects and remedy, Codes of cast inspection., Design considerations, Computer applications in metal casting and flow patterns. Advanced welding operations: Laser welding, Electron beam welding, Friction stir welding of different alloys and post weld heat treatment and dissimilar materials, Ultrasonic welding (USW) | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
2 | 6 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP252s | Casting & Welding (2) | 2 CH | |||||||||
Prerequisites | ( MDP251s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Casting techniques: die casting, continuous casting, centrifugal casting, ribbon casting, rheocasting, investment casting, casting defects and remedy, Codes of cast inspection., Design considerations, Computer applications in metal casting and flow patterns. Advanced welding operations: Laser welding, Electron beam welding, Friction stir welding of different alloys and post weld heat treatment and dissimilar materials, Ultrasonic welding (USW) | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP254 | Thermodynamics of Materials | 3 CH | |||||||||
Prerequisites | ( MEP111 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Treatment of the Laws of Thermodynamics and Their Applications to Equilibrium and the Properties of Materials. Gibbs Free Energy and Phase Diagrams, Describing the State of an Alloy, The Chemical Potential, Stored Energy in Solids, Isotropic and Anisotropic Material Properties, Elastic Work, Entropy Contents in Materials, Generalized Conditions for Equilibrium, the Gibbs Phase Rule and Its Applications, Solution Thermodynamics, Unstable Solutions, Equilibrium Conditions for Solid Solutions, Equilibrium Conditions for Charged Species, Introduction to Surface Thermodynamics. Aspects of Statistical Thermodynamics as they relate to Macroscopic Equilibrium Phenomena.  Introduction to Modelling of Thermodynamics Properties of Multiphase Equilibrium. Thermodynamic activity in solid and liquid systems, Gibbs free energy of solutions, binary phase diagrams, equilibrium constant, reaction equilibrium in gases, heats of reactions, stoichiometric phases with complex gas phases, mixed gas thermodynamics, Ellingham diagrams. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
2 | 5 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP254s | Thermodynamics of Materials | 3 CH | |||||||||
Prerequisites | ( MEP111s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Treatment of the Laws of Thermodynamics and Their Applications to Equilibrium and the Properties of Materials. Gibbs Free Energy and Phase Diagrams, Describing the State of an Alloy, The Chemical Potential, Stored Energy in Solids, Isotropic and Anisotropic Material Properties, Elastic Work, Entropy Contents in Materials, Generalized Conditions for Equilibrium, the Gibbs Phase Rule and Its Applications, Solution Thermodynamics, Unstable Solutions, Equilibrium Conditions for Solid Solutions, Equilibrium Conditions for Charged Species, Introduction to Surface Thermodynamics. Aspects of Statistical Thermodynamics as they relate to Macroscopic Equilibrium Phenomena. Introduction to Modelling of Thermodynamics Properties of Multiphase Equilibrium. Thermodynamic activity in solid and liquid systems, Gibbs free energy of solutions, binary phase diagrams, equilibrium constant, reaction equilibrium in gases, heats of reactions, stoichiometric phases with complex gas phases, mixed gas thermodynamics, Ellingham diagrams. | |||||||||||
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 | ||||||||
25% | 25% | 10% | 40% |
MDP255 | Materials Testing and Behavior | 3 CH | |||||||||
Prerequisites | ( MDP151 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Mechanical testing methods to produce data that will be used for design purposes or as part of a material joining procedure or operator acceptance scheme. Different mechanical testing (tensile, compression, bending, impact, hardness, fatigue, creep, etc.), factors affecting mechanical properties, introductory to some non-destructive testing. Material response to different external forces, factors affecting the mechanical behavior of materials, true stress-true strain relation and idealized models of deformation of materials, elastic and plastic deformation, yielding criteria, treatment of multiaxial stresses and strains, physical models (rheological) for elastic, plastic and creep deformation. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
2 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP255s | Materials Testing and Behavior | 3 CH | |||||||||
Prerequisites | ( MDP151s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Mechanical testing methods to produce data that will be used for design purposes or as part of a material joining procedure or operator acceptance scheme. Different mechanical testing (tensile, compression, bending, impact, hardness, fatigue, creep, etc.), factors affecting mechanical properties, introductory to some non-destructive testing. Material response to different external forces, factors affecting the mechanical behaviour of materials, true stress-true strain relation and idealized models of deformation of materials, elastic and plastic deformation, yielding criteria, treatment of multiaxial stresses and strains, physical models (rheological) for elastic, plastic and creep deformation. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |
MDP256 | Phase Transformation and Heat Treatment | 3 CH | |||||||||
Prerequisites | ( MDP152 OR MDP153 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
The use of heat treatment to produce required metallurgical properties, Cooling curves and equilibrium diagrams, Heat treatment of steels, phase transformation (e.g., martensitic transformations), Hardenability, Strength, and Toughness, Case hardening, Carburizing, and Nitriding, De-carburizing, Re-heat treatment, Re tempering, Annealing, and Normalizing, Heat treatment of Aluminium alloys, Annealing, Solution treatment, Natural ageing, Artificial ageing, Over ageing, Explanation of the heat treatment of Aluminium alloys, Control testing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
2 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP256s | Phase Transformation and Heat Treatment | 3 CH | |||||||||
Prerequisites | ( MDP152s OR MDP153s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
The use of heat treatment to produce required metallurgical properties, Cooling curves and equilibrium diagrams, Heat treatment of steels, phase transformation (e.g., martensitic transformations), Hardenability, Strength, and Toughness, Case hardening, Carburizing, and Nitriding, De-carburizing, Re-heat treatment, Re tempering, Annealing, and Normalizing, Heat treatment of Aluminium alloys, Annealing, Solution treatment, Natural ageing, Artificial ageing, Over ageing, Explanation of the heat treatment of Aluminium alloys, Control testing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |
MDP257 | Materials for Advanced Manufacturing Technology | 2 CH | |||||||||
Prerequisites | ( MDP183 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Advanced materials, advanced manufacturing techniques, mechanical, physical and electrical properties of materials used in advanced manufacturing technology, materials requirements in advanced manufacturing techniques. Electrical discharge machining (EDM), electrochemical machining (ECM), photochemical machining (PCM), ultrasonic machining, lasers cutting, plasma Cutting, rapid prototyping, hybrid machining, etc. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
3 | 1 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP257s | Materials for Advanced Manufacturing Technology | 2 CH | |||||||||
Prerequisites | ( MDP183s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Advanced materials, advanced manufacturing techniques, mechanical, physical and electrical properties of materials used in advanced manufacturing technology, materials requirements in advanced manufacturing techniques. Electrical discharge machining (EDM), electrochemical machining (ECM), photochemical machining (PCM), ultrasonic machining, lasers cutting, plasma Cutting, rapid prototyping, hybrid machining, etc. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |
MDP351 | Industrial Furnaces and Heat Treatment | 2 CH | |||||||||
Prerequisites | ( MDP152 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Classification of furnaces, Thermal furnaces (melting, drying, roasting, sintering and heat treatment), heat exchange and insulation materials, heat transfer and furnace design, fuel fired furnace, electric furnace, batch versus continuous furnaces, Elements of heat treating process, heat treatment types (stress relief, solution treatment, annealing, normalizing, quenching, tempering, ageing), heat treatment of steels, cast iron and nonferrous alloys. Case hardening, nitriding and carbonizing, surface hardening. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP351s | Industrial Furnaces and Heat Treatment | 2 CH | |||||||||
Prerequisites | ( MDP152s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Classification of furnaces, Thermal furnaces (melting, drying, roasting, sintering and heat treatment), heat exchange and insulation materials, heat transfer and furnace design, fuel fired furnace, electric furnace, batch versus continuous furnaces, Elements of heat treating process, heat treatment types (stress relief, solution treatment, annealing, normalizing, quenching, tempering, ageing), heat treatment of steels, cast iron and nonferrous alloys. Case hardening, nitriding and carbonizing, surface hardening. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP353 | Polymer Materials | 3 CH | |||||||||
Prerequisites | ( PHM242 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Structure of amorphous and crystalline polymeric materials, mechanical, electrical and optical properties and their modification through processing, Newtonian and non-Newtonian behaviour, viscoelastic behaviour, viscosity, review on destructive and non-destructive testing, mechanical analysis (DMA, TMA), quick overview on polymer processing technologies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP353s | Polymer Materials | 3 CH | |||||||||
Prerequisites | ( PHM242s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Structure of amorphous and crystalline polymeric materials, mechanical, electrical and optical properties and their modification through processing, Newtonian and non-Newtonian behaviour, viscoelastic behaviour, viscosity, review on destructive and non-destructive testing, mechanical analysis (DMA, TMA), quick overview on polymer processing technologies. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |
MDP354 | Industrial Project | 3 CH | |||||||||
Prerequisites | ( MDP255 ) AND ( MDP256 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
The project is to be completed within the student’s junior year. The student is requested to consider a simple engineering problem that is materials engineering related. The student should analyse the problem and find a systematic approach towards solving the problem. Practical work to achieve the goals are accomplished, the stages and results are analysed. By the end the student is requested to submit a technical report and make an oral presentation to persuade the audience of his approach. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
3 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 40% | 0% |
MDP354s | Industrial Project | 3 CH | |||||||||
Prerequisites | ( MDP255s ) AND ( MDP256s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
1 Hour | 0 Hours | 6 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
The project is to be completed within the student’s junior year. The student is requested to consider a simple engineering problem that is materials engineering related. The student should analyse the problem and find a systematic approach towards solving the problem. Practical work to achieve the goals are accomplished, the stages and results are analysed. By the end the student is requested to submit a technical report and make an oral presentation to persuade the audience of his approach. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MDP355 | Modern Ferrous and Non-Ferrous Making | 2 CH | |||||||||
Prerequisites | ( MDP254 ) AND ( MDP256 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Types of Metals, History of metals making, Status of steel and nonferrous metal making in Egypt and world, Steel, Aluminium, copper, Magnesium and Titanium production and consumption, metals making fundamentals: Solution thermodynamics, Role of slag in steelmaking, properties of slag. Steel making fundamentals: Steelmaking reactions such as oxidation of carbon, silicon, manganese, iron, phosphorous and chromium, Numerical problems, Role of refractory. Steel making practice: Bessemer and open-hearth steel making, Blast furnace iron making, Basic oxygen steel making, Electric furnace steel making and vacuum treatment, ladle metallurgy, deoxidation and teeming practice, ingot production, ingot defects and remedies, testing of steel products, inspection of steel products. Clean steel, ingot and continuous casting, final finishing operations like heat treatment and deformation processing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
3 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP355s | Modern Ferrous and Non-Ferrous Making | 2 CH | |||||||||
Prerequisites | ( MDP254s ) AND ( MDP256s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Types of Metals, History of metals making, Status of steel and nonferrous metal making in Egypt and world, Steel, Aluminium, copper, Magnesium and Titanium production and consumption, metals making fundamentals: Solution thermodynamics, Role of slag in steelmaking, properties of slag. Steel making fundamentals: Steelmaking reactions such as oxidation of carbon, silicon, manganese, iron, phosphorous and chromium, Numerical problems, Role of refractory. Steel making practice: Bessemer and open-hearth steel making, Blast furnace iron making, Basic oxygen steel making, Electric furnace steel making and vacuum treatment, ladle metallurgy, deoxidation and teeming practice, ingot production, ingot defects and remedies, testing of steel products, inspection of steel products. Clean steel, ingot and continuous casting, final finishing operations like heat treatment and deformation processing. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP356 | Glass, Ceramics, and Binding Materials | 3 CH | |||||||||
Prerequisites | ( MDP153 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to the non-metal and non-polymer class of materials, including glass, Ceramics and binding materials. Principles of glasses: glassy status, structure, thermodynamics, examples of glass formation (silicate, borate glasses), viscosity and brittleness, density and thermal strain, heat capacity and heat transfer, failure, dispersion and optic glasses, absorption, Ligandenfeld theory, coloration, ionic construction, electric conduction, dielectric loss, chemical resistance, corrosion, aging, dissolution, permeability, diffusion. Principles of ceramics: review on atomic structure (silica ceramics, oxide ceramics, non-oxide ceramics), characteristics. Principles of adhesive agents and construction materials: physical and chemical principles of multi material systems, Portland cements, other cements, calk, Testing and standardization, development of mineral adhesive agents. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
3 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP356s | Glass, Ceramics, and Binding Materials | 3 CH | |||||||||
Prerequisites | ( MDP153s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to the non-metal and non-polymer class of materials, including glass, Ceramics and binding materials. Principles of glasses: glassy status, structure, thermodynamics, examples of glass formation (silicate, borate glasses), viscosity and brittleness, density and thermal strain, heat capacity and heat transfer, failure, dispersion and optic glasses, absorption, Ligandenfeld theory, coloration, ionic construction, electric conduction, dielectric loss, chemical resistance, corrosion, aging, dissolution, permeability, diffusion. Principles of ceramics: review on atomic structure (silica ceramics, oxide ceramics, non-oxide ceramics), characteristics. Principles of adhesive agents and construction materials: physical and chemical principles of multi material systems, Portland cements, other cements, calk, Testing and standardization, development of mineral adhesive agents. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP451 | Failure Analysis | 3 CH | |||||||||
Prerequisites | ( MDP151 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
General approaches of Failure Analysis: data and sample collection, preliminary examination, non-destructive inspection, macroscopic and microscopic examination of metallographic sections and fractured surfaces, modes of failure (ductile, brittle) causes of failure (overloads, fatigue, creep, corrosion, wear, elevated temperature failures, etc.), solve the problems of cracks’ initiation and propagation, writing a standardized failure technical report, and failure prevention recommendations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
3 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP451s | Failure Analysis | 3 CH | |||||||||
Prerequisites | ( MDP151s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
General approaches of Failure Analysis: data and sample collection, preliminary examination, non-destructive inspection, macroscopic and microscopic examination of metallographic sections and fractured surfaces, modes of failure (ductile, brittle) causes of failure (overloads, fatigue, creep, corrosion, wear, elevated temperature failures, etc.), solve the problems of cracks’ initiation and propagation, writing a standardized failure technical report, and failure prevention recommendations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
|||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
10% | 10% | 20% | 60% |
MDP452 | Material and Process Selection | 3 CH | |||||||||
Prerequisites | ( MDP081 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Review traditional methods and new developments. Learn how a new material or manufacturing process can offer new design opportunities. Novel Strategies for Materials and Process Selection: Using ‘material-selection charts’ as a way of putting material performance and cost into perspective. Extracting criteria for materials and process selection from design requirements. The Concept of Optimal Selection: Maximizing performance and minimizing material cost or environmental impact by incorporating the concepts of cost, price and utility into the selection process. Optimal selection of material and shape: the interaction of material and shape in mechanical design. Database design and quality assurance: Types and sources of data, the structure of engineering selection, principles for designing selection databases, data checking, demonstration of commercial software Constructor data input module. Hands-on experience: Materials and process selection software and database creation software: demonstrations, and exercises. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 20% | 20% | 40% |
MDP452s | Material and Process Selection | 3 CH | |||||||||
Prerequisites | ( MDP081s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Review traditional methods and new developments. Learn how a new material or manufacturing process can offer new design opportunities. Novel Strategies for Materials and Process Selection: Using ‘material-selection charts’ as a way of putting material performance and cost into perspective. Extracting criteria for materials and process selection from design requirements. The Concept of Optimal Selection: Maximizing performance and minimizing material cost or environmental impact by incorporating the concepts of cost, price and utility into the selection process. Optimal selection of material and shape: the interaction of material and shape in mechanical design. Database design and quality assurance: Types and sources of data, the structure of engineering selection, principles for designing selection databases, data checking, demonstration of commercial software Constructor data input module. Hands-on experience: Materials and process selection software and database creation software: demonstrations, and exercises. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Mechanical Power Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
10% | 10% | 20% | 60% |
MDP453 | Composites Technology | 3 CH | |||||||||
Prerequisites | ( MDP151 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to the concepts of composite materials, matrix, reinforcement and interface, engineering matrices and reinforcements, production techniques for common reinforcing fibres, intrinsic properties of matrix materials and fibres, mechanical properties and fabrication of engineering composites including MMCs PMCs and CMCs, introduction to the mechanics of composites, rule of mixtures, methods for interfacial characterization. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 20% | 20% | 40% |
MDP453s | Composites Technology | 3 CH | |||||||||
Prerequisites | ( MDP151s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to the concepts of composite materials, matrix, reinforcement and interface, engineering matrices and reinforcements, production techniques for common reinforcing fibres, intrinsic properties of matrix materials and fibres, mechanical properties and fabrication of engineering composites including MMCs PMCs and CMCs, introduction to the mechanics of composites, rule of mixtures, methods for interfacial characterization. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
|||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
10% | 10% | 20% | 60% |
MDP454 | Corrosion | 3 CH | |||||||||
Prerequisites | ( MDP151 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction, corrosion types, atmospheric corrosion, principles of cathodic protection, corrosion by soils, corrosion by water and steam, localized corrosion, fundamentals of inhibitors, stress corrosion, metallurgical factors affecting corrosion, at high temperature, alloy behaviour at high temperature, coatings, corrosion testing, materials for corrosive environments, analysis of corrosion failure. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP454s | Corrosion | 3 CH | |||||||||
Prerequisites | ( MDP151s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction, corrosion types, atmospheric corrosion, principles of cathodic protection, corrosion by soils, corrosion by water and steam, localized corrosion, fundamentals of inhibitors, stress corrosion, metallurgical factors affecting corrosion, at high temperature, alloy behaviour at high temperature, coatings, corrosion testing, materials for corrosive environments, analysis of corrosion failure. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
|||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
10% | 10% | 20% | 60% |
MDP455 | Renewable Materials | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Definition of renewable materials (RM) and classification, Comparison between renewable and non-renewable resources, Principles guiding the use of RM, RM as a new challenge to engineering, The agricultural residues (AGR) as a base for competitive and comparative advantages, Machines for processing of AGR, Engineered products from AGR, Examples of use of RM in development: new products and opportunities, Open discussion on the course content and evaluation. Study of the structure of RM (Examples of palm midrib and sorghum stalk), Study of machines for stripping of palm midribs, Comparison between the mechanical properties of palm midrib inner layers and spruce, red European pine and beech woods, Comparison between the tensile strength of the palm midrib and sorghum stalk external layer and mild steel according to the tensile strength/density criterion, Study of the process of manufacture of palm midrib board, Mechanical testing of fibre bundles, Tensile test of polymer composite, Bending test of polymer composite, Microstructure investigation, Thermogravimetric analysis. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP455s | Renewable Materials | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Definition of renewable materials (RM) and classification, Comparison between renewable and non-renewable resources, Principles guiding the use of RM, RM as a new challenge to engineering, The agricultural residues (AGR) as a base for competitive and comparative advantages, Machines for processing of AGR, Engineered products from AGR, Examples of use of RM in development: new products and opportunities, Open discussion on the course content and evaluation. Study of the structure of RM (Examples of palm midrib and sorghum stalk), Study of machines for stripping of palm midribs, Comparison between the mechanical properties of palm midrib inner layers and spruce, red European pine and beech woods, Comparison between the tensile strength of the palm midrib and sorghum stalk external layer and mild steel according to the tensile strength/density criterion, Study of the process of manufacture of palm midrib board, Mechanical testing of fibre bundles, Tensile test of polymer composite, Bending test of polymer composite, Microstructure investigation, Thermogravimetric analysis. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
50% | 10% | 0% | 40% |
MDP456 | Petrochemicals and Polymer Products | 2 CH | |||||||||
Prerequisites | ( PHM141 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Origin and classification of petroleum; types and chemical composition of crude oil, routine laboratory tests of crude oil, Manufacturing Processes and Refinery of petroleum (Separation, Conversion and Refining and Treating); physical parameters of petroleum products (cracking; knocking, Diesel index, Octane number and factors affecting it. Gasoline), Effect of Sulphur compounds upon petroleum products, Diesel and biodiesel. Natural gas, Petrochemical process, Synthetic petrochemical, Petrochemical products based on natural gas and synthesis gas. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP456s | Petrochemicals and Polymer Products | 2 CH | |||||||||
Prerequisites | ( PHM141s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Origin and classification of petroleum; types and chemical composition of crude oil, routine laboratory tests of crude oil, Manufacturing Processes and Refinery of petroleum (Separation, Conversion and Refining and Treating); physical parameters of petroleum products (cracking; knocking, Diesel index, Octane number and factors affecting it. Gasoline), Effect of Sulphur compounds upon petroleum products, Diesel and biodiesel. Natural gas, Petrochemical process, Synthetic petrochemical, Petrochemical products based on natural gas and synthesis gas. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP457 | Extractive Metallurgy | 3 CH | |||||||||
Prerequisites | ( MDP183 ) AND ( MDP256 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Background of extraction, Thermodynamics, Oxides and Sulphides. Pyrometallurgical processes for iron and steel, copper and lead-Zinc production, Hydrometallurgical processes for uranium and gold, copper and alumina. Refractory gold ore treatment. Electrometallurgical refining/ winning for copper, zinc, precious metals and Aluminium. Developments in extraction and in bio metallurgy. Separation equipment, material handling devices. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP457s | Extractive Metallurgy | 3 CH | |||||||||
Prerequisites | ( MDP183s ) AND ( MDP256s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Background of extraction, Thermodynamics, Oxides and Sulphides. Pyrometallurgical processes for iron and steel, copper and lead-Zinc production, Hydrometallurgical processes for uranium and gold, copper and alumina. Refractory gold ore treatment. Electrometallurgical refining/ winning for copper, zinc, precious metals and Aluminium. Developments in extraction and in bio metallurgy. Separation equipment, material handling devices. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP458 | Material and Process Selection | 2 CH | |||||||||
Prerequisites | ( MDP081 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Novel Strategies for Materials and Process Selection: Using ‘material-selection charts’ as a way of putting material performance and cost into perspective. The Concept of Optimal Selection: Maximizing performance and minimizing material cost or environmental impact by incorporating the concepts of cost, price and utility into the selection process. Optimal selection of material and shape: the interaction of material and shape in mechanical design. Database design and quality assurance: Types and sources of data, the structure of engineering selection, principles for designing selection databases, data checking, demonstration of commercial software Constructor data input module. Hands-on experience: Materials and process selection software and database creation software: demonstrations, and exercises. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Manufacturing Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP458s | Material and Process Selection | 2 CH | |||||||||
Prerequisites | ( MDP081s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Novel Strategies for Materials and Process Selection: Using ‘material-selection charts’ as a way of putting material performance and cost into perspective. The Concept of Optimal Selection: Maximizing performance and minimizing material cost or environmental impact by incorporating the concepts of cost, price and utility into the selection process. Optimal selection of material and shape: the interaction of material and shape in mechanical design. Database design and quality assurance: Types and sources of data, the structure of engineering selection, principles for designing selection databases, data checking, demonstration of commercial software Constructor data input module. Hands-on experience: Materials and process selection software and database creation software: demonstrations, and exercises. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 20% | 0% | 50% |
MDP459 | Corrosion Control and Cathodic Protection | 3 CH | |||||||||
Prerequisites | ( MDP451 ) AND ( MDP454 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Corrosion resistant materials for specific environments. Controlling environmental parameters: dehumidification, temperature, velocity and pH control. Corrosion inhibitors: functions, classification, mechanisms, types, dose calculation. Painting and coating systems: surface preparation, applying coats, coating systems, painting, coating testing and inspection. Cathodic protection: theory of cathodic protection. Impressed current CP and sacrificial anode CP systems. Anode materials. Anode current capacity and anode efficiency. Calculation of protection current. Cathodic protection systems: calculation of anode weight and distribution, installation and inspection. Case study. Anodic protection system. Corrosion monitoring, testing and inspection. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | 1 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP459s | Corrosion Control and Cathodic Protection | 3 CH | |||||||||
Prerequisites | ( MDP451s ) AND ( MDP454s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Corrosion resistant materials for specific environments. Controlling environmental parameters: dehumidification, temperature, velocity and pH control. Corrosion inhibitors: functions, classification, mechanisms, types, dose calculation. Painting and coating systems: surface preparation, applying coats, coating systems, painting, coating testing and inspection. Cathodic protection: theory of cathodic protection. Impressed current CP and sacrificial anode CP systems. Anode materials. Anode current capacity and anode efficiency. Calculation of protection current. Cathodic protection systems: calculation of anode weight and distribution, installation and inspection. Case study. Anodic protection system. Corrosion monitoring, testing and inspection. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP460 | Non-destructive Testing of Materials (1) | 3 CH | |||||||||
Prerequisites | ( MDP255 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Motivation to NDT, Scope of tested products such as weld lines/ castings/ forgings/ textile reinforced plastics, NDT selection chart according to the process, material and expected flaw size, Types of NDT: Visual inspection/ Die penetrant test/ Thermography/ Radiography/ Ultrasonic/ Acoustic Emission/ Magnetic test/ Eddy current/ Computer tomography, Case studies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
5 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP460s | Non-destructive Testing of Materials (1) | 3 CH | |||||||||
Prerequisites | ( MDP255s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Motivation to NDT, Scope of tested products such as weld lines/ castings/ forgings/ textile reinforced plastics, NDT selection chart according to the process, material and expected flaw size, Types of NDT: Visual inspection/ Die penetrant test/ Thermography/ Radiography/ Ultrasonic/ Acoustic Emission/ Magnetic test/ Eddy current/ Computer tomography, Case studies. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP461 | Non-destructive Testing of Materials (2) | 3 CH | |||||||||
Prerequisites | ( MDP460 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Visual inspection (VT): Joining and metal forming processes and developments of discontinuities, In-service discontinuities with respect to stress and corrosion, Tools for VT. Die penetrant test (PT): Scope of application, proper use and calibration of media and equipment, and an overview of the origin and nature of discontinuities, technique demonstrations and hands-on lab exercises. Magnetic test (MT): Basic theory of magnetism, applications for the testing of ferromagnetic materials. Technique demonstrations and hands-on lab exercises. Ultrasonic test (UT): Review of basic ultrasonic theory, evaluation of weldments, innovative techniques to detect and evaluate discontinuities, equipment and advanced calibration methods, demonstrations and hands-on lab exercises. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
5 | 2 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP461s | Non-destructive Testing of Materials (2) | 3 CH | |||||||||
Prerequisites | ( MDP460s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Visual inspection (VT): Joining and metal forming processes and developments of discontinuities, In-service discontinuities with respect to stress and corrosion, Tools for VT. Die penetrant test (PT): Scope of application, proper use and calibration of media and equipment, and an overview of the origin and nature of discontinuities, technique demonstrations and hands-on lab exercises. Magnetic test (MT): Basic theory of magnetism, applications for the testing of ferromagnetic materials. Technique demonstrations and hands-on lab exercises. Ultrasonic test (UT): Review of basic ultrasonic theory, evaluation of weldments, innovative techniques to detect and evaluate discontinuities, equipment and advanced calibration methods, demonstrations and hands-on lab exercises. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP462 | Polymeric Processing Techniques | 2 CH | |||||||||
Prerequisites | MDP151 | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
An introduction to the basic principles of polymer processing, mixing, extrusion (single and twin-screw extruders, foils, plates, profiles, blow forming), injection moulding, reactive processing, injection moulding-related processes, decorative moulding, extrusion and injection blow moulding, compression moulding, thermoforming, coating … etc. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP462s | Polymeric Processing Techniques | 2 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
An introduction to the basic principles of polymer processing, mixing, extrusion (single and twin-screw extruders, foils, plates, profiles, blow forming), injection moulding, reactive processing, injection moulding related processes, decorative moulding, extrusion and injection blow moulding, compression moulding, thermoforming, coating … etc. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP463 | Materials for Energy Solution | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MDP353 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Operating principles and applications of emerging technological solutions to the energy demands of the world. The scale of global energy usage and requirements for possible solutions. Basic physics and chemistry of solar cells, fuel cells, and batteries. Performance issues, including economics, from the ideal device to the installed system. The promise of materials research for providing next generation solutions. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP463s | Materials for Energy Solution | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MDP353s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Operating principles and applications of emerging technological solutions to the energy demands of the world. The scale of global energy usage and requirements for possible solutions. Basic physics and chemistry of solar cells, fuel cells, and batteries. Performance issues, including economics, from the ideal device to the installed system. The promise of materials research for providing next generation solutions. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP464 | Surfactants and lubricating Materials | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MDP353 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Lubrication properties, types of lubricants, solid, waxy and oil, Interdisciplinary materials on lubrication in machine design including mechanical, mechanics and chemistry aspects, engineering tribology, surface topography, topographical measurements and characterization and classification of regimes of lubrication types of industrial lubricants, properties of lubricating oils: compositions, viscosity and additives, synthetic lubricants and engine oils. Hydrodynamic lubrication. The last topic to be covered is the theory and application of Elasto-hydrodynamic lubrication (EHL). | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP464s | Surfactants and lubricating Materials | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MDP353s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Lubrication properties, types of lubricants, solid, waxy and oil, Interdisciplinary materials on lubrication in machine design including mechanical, mechanics and chemistry aspects, engineering tribology, surface topography, topographical measurements and characterization and classification of regimes of lubrication types of industrial lubricants, properties of lubricating oils: compositions, viscosity and additives, synthetic lubricants and engine oils. Hydrodynamic lubrication. The last topic to be covered is the theory and application of Elasto-hydrodynamic lubrication (EHL). | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP465 | Rubber and Sealing Materials | 3 CH | |||||||||
Prerequisites | ( MEP212 ) AND ( MDP353 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to rubbers and sealing materials, Natural rubber, chemical arrangement of natural rubber, synthetic rubber, types of synthetic rubber, Vulcanization of rubber. Thermoplastic rubber, chain of thermoplastic rubber, sealing materials, rubber processing (silicon rubber injection, etc.) | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP465s | Rubber and Sealing Materials | 3 CH | |||||||||
Prerequisites | ( MEP212s ) AND ( MDP353s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to rubbers and sealing materials, Natural rubber, chemical arrangement of natural rubber, synthetic rubber, types of synthetic rubber, Vulcanization of rubber. Thermoplastic rubber, chain of thermoplastic rubber, sealing materials, rubber processing (silicon rubber injection, etc.) | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP466 | Polymer Processing | 3 CH | |||||||||
Prerequisites | ( MDP353 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Types of polymer materials, Physical and mechanical properties of polymers. Process paraments of polymer processing. An introduction to the basic principles of polymer processing, mixing, extrusion (single and twin-screw extruders, foils, plates, profiles, blow forming), injection moulding, reactive processing, injection moulding related processes, decorative moulding, extrusion and injection blow moulding, compression moulding, thermoforming, coating … etc. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP466s | Polymer Processing | 3 CH | |||||||||
Prerequisites | ( MDP353s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Types of polymer materials, Physical and mechanical properties of polymers. Process paraments of polymer processing. An introduction to the basic principles of polymer processing, mixing, extrusion (single and twin-screw extruders, foils, plates, profiles, blow forming), injection moulding, reactive processing, injection moulding related processes, decorative moulding, extrusion and injection blow moulding, compression moulding, thermoforming, coating … etc. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP467 | Polymer Testing | 3 CH | |||||||||
Prerequisites | ( MDP353 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to the significance of polymer testing and its applications, short destructive testing showing the effect of test speed (tension, compression, impact, torsion), long destructive testing (relaxation, retardation, fatigue), thermal analysis (DTA, TGA, DSC), mechanical analysis (DMA, TMA), special techniques (μTA), chemical analysis, non-destructive testing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Materials Engineering |
5 | 2 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP467s | Polymer Testing | 3 CH | |||||||||
Prerequisites | ( MDP353s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to the significance of polymer testing and its applications, short destructive testing showing the effect of test speed (tension, compression, impact, torsion), long destructive testing (relaxation, retardation, fatigue), thermal analysis (DTA, TGA, DSC), mechanical analysis (DMA, TMA), special techniques (μTA), chemical analysis, non-destructive testing. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP468 | Materials Characterization | 3 CH | |||||||||
Prerequisites | ( MDP255 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to characterization, characterization techniques, principles, analysis and applications: optical metallography, measurements and analysis, quantitative analysis, SEM, EDX, TEM, x-ray diffraction, AFM, introduction to thermal analyses methods (TGA, DSC, DMA, DTA) etc. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP468s | Materials Characterization | 3 CH | |||||||||
Prerequisites | ( MDP255s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to characterization, characterization techniques, principles, analysis and applications: optical metallography, measurements and analysis, quantitative analysis, SEM, EDX, TEM, x-ray diffraction, AFM, introduction to thermal analyses methods (TGA, DSC, DMA, DTA) etc. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP469 | Glasses Materials and Technology | 3 CH | |||||||||
Prerequisites | ( MDP356 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to materials, the glassy state, definition of glass, raw materials, viscosity, brittleness, batch calculations, colorizing/decolorizing glass, glass processing techniques, annealing, glass ingredients, properties of glasses, production technology and glass reaction, glass cullet, technology of sun glasses, glass ceramics and its recent applications, Nano-glass ceramic, smart glass technologies including: electrochromic glass, liquid crystal glazing, self-cleaning glass, photovoltaic glass float glass, alarm glass, fire-resistant glass, and body-tinted glass, types of sheet glasses: reflective glass, low-e glass, mirror, insulating glass, enamelled/screen printed glass, pattern glass, antique mirror, x-ray protection glass, electrically heated glass, sand-blasted glass , acid-etched glass, tempered glass, laminated glass, wired glass, anti-reflective glass, glass defects, fibre glass and physical properties of glass, thermal expansion for various types of glasses. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP469s | Glasses Materials and Technology | 3 CH | |||||||||
Prerequisites | ( MDP356s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to materials, the glassy state, definition of glass, raw materials, viscosity, brittleness, batch calculations, colorizing/decolorizing glass, glass processing techniques, annealing, glass ingredients, properties of glasses, production technology and glass reaction, glass cullet, technology of sun glasses, glass ceramics and its recent applications, Nano-glass ceramic, smart glass technologies including: electrochromic glass, liquid crystal glazing, self-cleaning glass, photovoltaic glass float glass, alarm glass, fire-resistant glass, and body-tinted glass, types of sheet glasses: reflective glass, low-e glass, mirror, insulating glass, enamelled/screen printed glass, pattern glass, antique mirror, x-ray protection glass, electrically heated glass, sand-blasted glass , acid-etched glass, tempered glass, laminated glass, wired glass, anti-reflective glass, glass defects, fibre glass and physical properties of glass, thermal expansion for various types of glasses. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP470 | Ceramic Materials and Technology | 3 CH | |||||||||
Prerequisites | ( MDP356 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Ceramics: (definition, traditional and advanced ceramics, what the future may hold for advanced ceramics). Advanced Processing Concepts for increased ceramic reliability: (processing methods, glass-ceramic methods, gelation methods, powder methods, densification concepts, grain growth and densification, heterogeneities associated with powder processing, colloidal methods for preparing and consolidating powders). Wet forming processes as a potential solution of agglomeration problems: (the green microstructure, origin and nature of agglomerates, development of the green microstructure). Processing of electronic ceramics: (powder preparation, mixing, milling, drying, dry forming, tape casting, slip casting, sintering. Processing of ceramic composites: (composite mechanisms, composite processing, sintering of composites, particulate composites, whisker composites, fibre composites) | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP470s | Ceramic Materials and Technology | 3 CH | |||||||||
Prerequisites | ( MDP356s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Ceramics: (definition, traditional and advanced ceramics, what the future may hold for advanced ceramics). Advanced Processing Concepts for increased ceramic reliability: (processing methods, glass-ceramic methods, gelation methods, powder methods, densification concepts, grain growth and densification, heterogeneities associated with powder processing, colloidal methods for preparing and consolidating powders). Wet forming processes as a potential solution of agglomeration problems: (the green microstructure, origin and nature of agglomerates, development of the green microstructure). Processing of electronic ceramics: (powder preparation, mixing, milling, drying, dry forming, tape casting, slip casting, sintering. Processing of ceramic composites: (composite mechanisms, composite processing, sintering of composites, particulate composites, whisker composites, fibre composites) | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP471 | Binding Materials and Technology | 3 CH | |||||||||
Prerequisites | ( MDP356 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Principles of binding agents: (introduction, thermal behaviour, general concepts of binding). Inorganic binders: cement, lime, gypsum, occurrence, methods for preparation, initial and final setting times, normal consistency, accelerators, retarders, drying, shrinkage, water absorption, durability, mechanical properties, aggregates. Organic binders: epoxy resin, acrylic emulsion, admixtures). Advantages and disadvantages of concrete, geopolymers and its composites. Biocements. Cements for biomedical applications. Bone cementing | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP471s | Binding Materials and Technology | 3 CH | |||||||||
Prerequisites | ( MDP356s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Principles of binding agents: (introduction, thermal behaviour, general concepts of binding). Inorganic binders: cement, lime, gypsum, occurrence, methods for preparation, initial and final setting times, normal consistency, accelerators, retarders, drying, shrinkage, water absorption, durability, mechanical properties, aggregates. Organic binders: epoxy resin, acrylic emulsion, admixtures). Advantages and disadvantages of concrete, geopolymers and its composites. Biocements. Cements for biomedical applications. Bone cementing | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP472 | Biomedical Materials | 3 CH | |||||||||
Prerequisites | ( MDP356 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Reviews of biological materials (mechanical and physical properties of bone, cartilage, vessels, skin, muscle and the variety of collagen based biological materials), use of metals clinically in joint replacement, use of ceramics in Medicine, polymer and composite material and filler selection for soft tissue replacement (e.g., heart valves), implants, percutaneous prosthetics, and active devices, introduction to the analysis of surfaces, particularly by electron spectroscopy, surface coatings and treatments used to achieve biocompatibility, introduction to the mechanical and physical properties of shape memory alloys, their current clinical use and their clinical potential. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP472s | Biomedical Materials | 3 CH | |||||||||
Prerequisites | ( MDP356s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Reviews of biological materials (mechanical and physical properties of bone, cartilage, vessels, skin, muscle and the variety of collagen based biological materials), use of metals clinically in joint replacement, use of ceramics in Medicine, polymer and composite material and filler selection for soft tissue replacement (e.g., heart valves), implants, percutaneous prosthetics, and active devices, introduction to the analysis of surfaces, particularly by electron spectroscopy, surface coatings and treatments used to achieve biocompatibility, introduction to the mechanical and physical properties of shape memory alloys, their current clinical use and their clinical potential. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP473 | Introduction to Nano technology | 3 CH | |||||||||
Prerequisites | ( PHM121 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Nano technology, engineering of Nano-materials with emphasis on structural, optical, photonic, magnetic and electronic materials. Synthetic methods and analytical characterization with design for applications. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP473s | Introduction to Nano technology | 3 CH | |||||||||
Prerequisites | ( PHM121s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to Nano technology, engineering of Nano-materials with emphasis on structural, optical, photonic, magnetic and electronic materials. Synthetic methods and analytical characterization with design for applications. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP081 | Production Engineering | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
This course aims to provide engineering students with a simple introduction and general knowledge about engineering parts, their materials, and primary production processes and manufacturing technologies. It includes engineering materials classification, characteristics, and materials selection for different applications. Production processes such as casting, joining and metal forming processes. Some manufacturing processes of polymers, machining processes of metals. Machining processes of wood and Measuring instrumentations. In addition, a brief view on new materials (e.g. Nano-materials, metallic glass… etc.) and advanced processing techniques (e.g., CNC, high deformation rate, water jet cutting…. Etc.) is provided. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
0 | 2 | |||||||||
Manufacturing Engineering |
0 | 2 | |||||||||
Mechatronics Engineering and Automation |
0 | 2 | |||||||||
Landscape Architecture |
0 | 2 | |||||||||
Environmental Architecture and Urbanism |
0 | 2 | |||||||||
Housing Architecture and Urban Development |
0 | 2 | |||||||||
Communication Systems Engineering |
0 | 2 | |||||||||
Energy and Renewable Energy Engineering |
0 | 2 | |||||||||
Computer Engineering and Software Systems |
0 | 2 | |||||||||
Building Engineering |
0 | 2 | |||||||||
Civil Infrastructure Engineering |
0 | 2 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP081s | Production Engineering | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
This course aims to provide engineering students with a simple introduction and general knowledge about engineering parts, their materials, and primary production processes and manufacturing technologies. It includes engineering materials classification, characteristics, and materials selection for different applications. Production processes such as casting, joining and metal forming processes. Some manufacturing processes of polymers, machining processes of metals. Machining processes of wood and Measuring instrumentations. In addition, a brief view on new materials (e.g. Nano-materials, metallic glass… etc.) and advanced processing techniques (e.g., CNC, high deformation rate, water jet cutting…. Etc.) is provided. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
2 | ||||||||||
Mechanical Power Engineering |
2 | ||||||||||
Automotive Engineering |
2 | ||||||||||
Mechatronics Engineering |
2 | ||||||||||
Architectural Engineering |
2 | ||||||||||
Electrical Power and Machines Engineering |
2 | ||||||||||
Electronics and Communications Engineering |
2 | ||||||||||
Computer and Systems Engineering |
2 | ||||||||||
Structural Engineering |
2 | ||||||||||
Water Engineering and Hydraulic Structures |
2 | ||||||||||
Utilities and Infrastructure |
2 | ||||||||||
Freshmen Level |
0 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 15% | 10% | 50% |
MDP181 | Manufacturing Technology (1) | 3 CH | |||||||||
Prerequisites | ( MDP081 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Machining: Principles of machining, Turning machines and processes, Drilling machines and processes, Shaping and planning machines and processes, Milling machines and processes, Methods of tools and work piece fixation, Machining time, Introduction to Non-conventional machining processes. Forming: Introduction includes mechanical behaviour of the materials, Plastic deformation, Effect of temperature on plastic behaviour, Types of forming processes: Hot, Cold, Massive or sheet metal work, Metal forming processes: Forging and its types, Rolling, Extrusion, Types of drawing (rod, wire, tube, and deep), Sheet metal work (shearing, pressing, blanking, spinning, bending, coining, etc.), Brief explanation to forming machines and equipment. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Energy and Renewable Energy Engineering |
2 | 4 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MDP181s | Manufacturing Technology (1) | 3 CH | |||||||||
Prerequisites | ( MDP081s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Machining: Principles of machining, Turning machines and processes, Drilling machines and processes, Shaping and planning machines and processes, Milling machines and processes, Methods of tools and work piece fixation, Machining time, Introduction to Non-conventional machining processes. Forming: Introduction includes mechanical behaviour of the materials, Plastic deformation, Effect of temperature on plastic behaviour, Types of forming processes: Hot, Cold, Massive or sheet metal work, Metal forming processes: Forging and its types, Rolling, Extrusion, Types of drawing (rod, wire, tube, and deep), Sheet metal work (shearing, pressing, blanking, spinning, bending, coining, etc.), Brief explanation to forming machines and equipment. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
General Mechanical Engineering |
2 | ||||||||||
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 | ||||||||
20% | 25% | 15% | 40% |
MDP182 | Metal Forming Theory and Processes | 3 CH | |||||||||
Prerequisites | ( MDP081 ) AND ( MDP151 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 3 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Deformation and recrystallization, Cold and hot working, Strain hardening, Analysis of stress and strain, Forging and its types, calculation of loads required to metal forming, Forging and dimensional changes, Calculation of load during friction and frictionless drawing and upsetting, Rolling and Calculation of load, Torque and rolling mill power, Extrusion and metal flow, Extrusion pressure diagram, Calculation of friction and frictionless extrusion pressure and parameters affecting extrusion, Wire and tube drawing and wire drawing die, Calculation of friction and frictionless wire drawing load, Stress strain curve and maximum reduction permissible, Deep drawing and dimensional changes in flange and wall thickness, Calculation of deep drawing load, Redrawing and parameters affecting deep drawing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
1 | 4 | |||||||||
Manufacturing Engineering |
2 | 3 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP182s | Metal Forming Theory and Processes | 3 CH | |||||||||
Prerequisites | ( MDP081s ) AND ( MDP151s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 3 Hours | |||||||||
Required SWL | 175 | Equivalent ECTS | 7 | ||||||||
Course Content | |||||||||||
Deformation and recrystallization, Cold and hot working, Strain hardening, Analysis of stress and strain, Forging and its types, calculation of loads required to metal forming, Forging and dimensional changes, Calculation of load during friction and frictionless drawing and upsetting, Rolling and Calculation of load, Torque and rolling mill power, Extrusion and metal flow, Extrusion pressure diagram, Calculation of friction and frictionless extrusion pressure and parameters affecting extrusion, Wire and tube drawing and wire drawing die, Calculation of friction and frictionless wire drawing load, Stress strain curve and maximum reduction permissible, Deep drawing and dimensional changes in flange and wall thickness, Calculation of deep drawing load, Redrawing and parameters affecting deep drawing. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP183 | Manufacturing Technologies | 4 CH | |||||||||
Prerequisites | ( MDP081 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to manufacturing, Casting processes: Sand casting: Gating and raiser design, Die casting, Centrifugal casting, Investment casting. Metal forming processes: Rolling, Forging, Extrusion, Drawing, Sheet metal working (shear, bending…). Joining of metals, Welding processes: Oxy-Acetylene Welding, Arc welding, Submerged arc welding, Resistance welding, Spot and seam welding, Cold pressure welding, Adhesive welding. Machining Processes: Principles of machining, Materials of cutting tools, Sawing, Turning, Shaping, Planning and Slotting, Broaching, Drilling, Milling, and Grinding process and the details of the machines. Methods of tools and work piece fixation, machining time. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
1 | 4 | |||||||||
Mechatronics Engineering and Automation |
1 | 3 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP183s | Manufacturing Technologies | 4 CH | |||||||||
Prerequisites | ( MDP081s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Introduction to manufacturing, Casting processes: Sand casting: Gating and raiser design, Die casting, Centrifugal casting, Investment casting. Metal forming processes: Rolling, Forging, Extrusion, Drawing, Sheet metal working (shear, bending…). Joining of metals, Welding processes: Oxy-Acetylene Welding, Arc welding, Submerged arc welding, Resistance welding, Spot and seam welding, Cold pressure welding, Adhesive welding. Machining Processes: Principles of machining, Materials of cutting tools, Sawing, Turning, Shaping, Planning and Slotting, Broaching, Drilling, Milling, and Grinding process and the details of the machines. Methods of tools and work piece fixation, machining time. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |
MDP281 | Metal Cutting Theory and Technologies | 4 CH | |||||||||
Prerequisites | ( MDP081 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 3 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Principles of machining, Materials of cutting tools, Turning machines, forces and processes, Drilling machines, forces and processes, Shaping and planning machines, forces and processes, Milling machines, forces and processes, Grinding machines and processes, Methods of tools and work piece fixation, Machining time, Sequence of Technological processes and operations, process sheet, operation sheet. Screws manufacturing, Gear cutting. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
2 | 5 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP281s | Metal Cutting Theory and Technologies | 4 CH | |||||||||
Prerequisites | ( MDP081s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 3 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Principles of machining, Materials of cutting tools, Turning machines, forces and processes, Drilling machines, forces and processes, Shaping and planning machines, forces and processes, Milling machines, forces and processes, Grinding machines and processes, Methods of tools and work piece fixation, Machining time, Sequence of Technological processes and operations, process sheet, operation sheet. Screws manufacturing, Gear cutting. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP282 | Non-Conventional Processing | 2 CH | |||||||||
Prerequisites | ( MDP182 ) AND ( PHM041 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Chemical and Photochemical Machining (CHM), Electrochemical Machining (ECM), Electrochemical Deburring (ECD), Ultrasonic Machining (USM), Electro Discharge Machining (EDM sinking), EDM wire cutting, Laser Beam Machining (LBM), Electron Beam Machining (EBM), Water Jet Machining (WJM), Abrasive Water Jet Machining (AWJM), Abrasive Flow Machining (AFM). Rapid Prototype technique. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
2 | 6 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP282s | Non-Conventional Processing | 2 CH | |||||||||
Prerequisites | ( MDP182s ) AND ( PHM041s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 2 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Chemical and Photochemical Machining (CHM), Electrochemical Machining (ECM), Electrochemical Deburring (ECD), Ultrasonic Machining (USM), Electro Discharge Machining (EDM sinking), EDM wire cutting, Laser Beam Machining (LBM), Electron Beam Machining (EBM), Water Jet Machining (WJM), Abrasive Water Jet Machining (AWJM), Abrasive Flow Machining (AFM). Rapid Prototype technique. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP381 | Theory of Metal Forming | 3 CH | |||||||||
Prerequisites | ( MDP181 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Engineering and true stress and strain, Stress strain curves and models of mechanical behaviour, Strain rate and its effect on stress strain curve, Deformation and recrystallization, Cold and hot working, Strain hardening, Plastic deformation of metals, Yield criteria, Forging and dimensional changes, Calculation of load during drawing and upsetting, Factors affecting forging load, Rolling and neutral point, Calculation of load rolling mill power, Factors affecting rolling load, Extrusion and metal flow, Extrusion pressure diagram, Calculation of extrusion pressure and parameters affecting extrusion, Wire drawing and wire drawing die, Calculation of wire drawing load, Optimum wire drawing die angle and parameters affecting wire drawing. Tube drawing and dimensional changes in diameter and wall thickness, Calculation of drawing thin walled tubes, Plug tube drawing and mandrel tube drawing. Deep drawing and dimensional changes in flange and wall thickness, Calculation of deep drawing load, parameters affecting deep drawing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Materials Engineering |
5 | 2 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP381s | Theory of Metal Forming | 3 CH | |||||||||
Prerequisites | ( MDP181s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Engineering and true stress and strain, Stress strain curves and models of mechanical behaviour, Strain rate and its effect on stress strain curve, Deformation and recrystallization, Cold and hot working, Strain hardening, Plastic deformation of metals, Yield criteria, Forging and dimensional changes, Calculation of load during drawing and upsetting, Factors affecting forging load, Rolling and neutral point, Calculation of load rolling mill power, Factors affecting rolling load, Extrusion and metal flow, Extrusion pressure diagram, Calculation of extrusion pressure and parameters affecting extrusion, Wire drawing and wire drawing die, Calculation of wire drawing load, Optimum wire drawing die angle and parameters affecting wire drawing. Tube drawing and dimensional changes in diameter and wall thickness, Calculation of drawing thin walled tubes, Plug tube drawing and mandrel tube drawing. Deep drawing and dimensional changes in flange and wall thickness, Calculation of deep drawing load, parameters affecting deep drawing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP382 | Theory of Metal Cutting | 3 CH | |||||||||
Prerequisites | ( MDP181 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Basic concepts and definitions, Tool geometry (definitions, reference planes, geometry of single point tools, twist drills and milling cutters), Tool materials (types and applications), Chip formation (types of chips, built up edge BUE, chip compression ratio, determination of shear angle and shear strain), Mechanics of metal cutting (merchant’s analysis, factors affecting cutting forces), Measurement of the cutting forces, Empirical cutting force relationships in conventional cutting (turning, drilling and milling), Heat in metal cutting (heat generation and dissipation, cutting temperature, measurement, distribution, relationships of cutting temperature), Tool failure (types and causes), Tool wear and its measurement, Tool life, Taylor’s relationship, Factors affecting tool life, Chatter in machining (causes, measurements, limiting width of cut, factors, affecting the limiting width of cut), Cutting fluids (functions, requirements, types and applications), Surface roughness (sources, parameters, factors affecting surface roughness, theoretical relationship), Machining economy (machining cost equation, optimum tool life, optimum machining variables), Machinability (definitions, criteria and indices). | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP382s | Theory of Metal Cutting | 3 CH | |||||||||
Prerequisites | ( MDP181s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Basic concepts and definitions, Tool geometry (definitions, reference planes, geometry of single point tools, twist drills and milling cutters), Tool materials (types and applications), Chip formation (types of chips, built up edge BUE, chip compression ratio, determination of shear angle and shear strain), Mechanics of metal cutting (merchant’s analysis, factors affecting cutting forces), Measurement of the cutting forces, Empirical cutting force relationships in conventional cutting (turning, drilling and milling), Heat in metal cutting (heat generation and dissipation, cutting temperature, measurement, distribution, relationships of cutting temperature), Tool failure (types and causes), Tool wear and its measurement, Tool life, Taylor’s relationship, Factors affecting tool life, Chatter in machining (causes, measurements, limiting width of cut, factors, affecting the limiting width of cut), Cutting fluids (functions, requirements, types and applications), Surface roughness (sources, parameters, factors affecting surface roughness, theoretical relationship), Machining economy (machining cost equation, optimum tool life, optimum machining variables), Machinability (definitions, criteria and indices). | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP383 | Metal Forming Technology, Machines and Dies | 3 CH | |||||||||
Prerequisites | ( MDP181 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Metal forming technology: process, product design of forgings, rolling sections, extrusion, wire, tube and deep drawing. Powder metallurgy (powder production, compaction, sintering and sizing). Metal forming machines: types, details, parts and operation including forging hammers, presses, horizontal forging machines, rolling mills, extrusion presses, wire and tube drawing and deep drawing. Metal forming Dies design: forging, roll pass, extrusion, wire, tube and deep drawing of cylindrical cup with and without flanges. Quadratic and rectangular shapes, ironing. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP383s | Metal Forming Technology, Machines and Dies | 3 CH | |||||||||
Prerequisites | ( MDP181s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Metal forming technology: process, product design of forgings, rolling sections, extrusion, wire, tube and deep drawing. Powder metallurgy (powder production, compaction, sintering and sizing). Metal forming machines: types, details, parts and operation including forging hammers, presses, horizontal forging machines, rolling mills, extrusion presses, wire and tube drawing and deep drawing. Metal forming Dies design: forging, roll pass, extrusion, wire, tube and deep drawing of cylindrical cup with and without flanges. Quadratic and rectangular shapes, ironing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 7 | |||||||||
Design and Production Engineering |
4 | 2 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP384 | Metal Cutting Machines and Technology | 3 CH | |||||||||
Prerequisites | ( MDP181 ) AND ( MDP211 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Rigidity of machine tools and the accuracy of production, Spindles of machine tools, Frame parts of machine tools, Drives of machine tools, Machining tolerance and allowances, Process and operation sheet preparation, Capstan and turret lathes, Hobbing and gear shaping machines, Gear cutting operations, Grinding operations, Super finishing operations. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP384s | Metal Cutting Machines and Technology | 3 CH | |||||||||
Prerequisites | ( MDP181s ) AND ( MDP211s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 2 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Rigidity of machine tools and the accuracy of production, Spindles of machine tools, Frame parts of machine tools, Drives of machine tools, Machining tolerance and allowances, Process and operation sheet preparation, Capstan and turret lathes, Hobbing and gear shaping machines, Gear cutting operations, Grinding operations, Super finishing operations. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP385 | Manufacturing Processes | 2 CH | |||||||||
Prerequisites | ( MDP182 ) AND ( MDP281 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Sheet metal work (shearing, pressing, blanking, spinning, bending, coining, etc.), Brief explanation to forming machines and equipment. Rolling lines: Coil-pass design, High-energy-rate terming (explosive, electro-hydraulic, electro-magnetic forming), Powder metallurgy (powder production, compaction, sintering and sizing), Super finishing and metal coating. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP385s | Manufacturing Processes | 2 CH | |||||||||
Prerequisites | ( MDP182s ) AND ( MDP281s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Sheet metal work (shearing, pressing, blanking, spinning, bending, coining, etc.), Brief explanation to forming machines and equipment. Rolling lines: Coil-pass design, High-energy-rate terming (explosive, electro-hydraulic, electro-magnetic forming), Powder metallurgy (powder production, compaction, sintering and sizing), Super finishing and metal coating. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP386 | Computer Aided Manufacturing | 3 CH | |||||||||
Prerequisites | ( MDP281 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Computer technology, The foundations of CAD/CAM. Computer aided design: Fundamentals of CAD, The design process, Applications of computers for design, Computer-aided design software, Wire frame models, Solid modelling. Computer-aided manufacturing: Automation of manufacturing processes, Numerically controlled machines, Computerized numerically controlled machines (CNC), G codes, Programming languages, Applications and performance of CAD/CAM systems. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP386s | Computer Aided Manufacturing | 3 CH | |||||||||
Prerequisites | ( MDP281s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Computer technology, The foundations of CAD/CAM. Computer aided design: Fundamentals of CAD, The design process, Applications of computers for design, Computer-aided design software, Wire frame models, Solid modelling. Computer-aided manufacturing: Automation of manufacturing processes, Numerically controlled machines, Computerized numerically controlled machines (CNC), G codes, Programming languages, Applications and performance of CAD/CAM systems. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP387 | Metrology | 3 CH | |||||||||
Prerequisites | ( MDP281 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
International system of units, Theory of measurements, Instrument classification, Types of magnification (mechanical, electrical, optical, pneumatic), Fits, Tolerances and limit gauges, Simple measuring Instruments (Vernier, micrometres, dial gauges, angle gauges, protractors, sine bar, sensitive level), Comparators, Measuring machines, Errors and calibration of measuring equipment, Indirect measurements, Screw thread and gear measurements, Surface roughness measurements (2D and 3D measurement), Static tests for machine tools, Advanced measuring techniques (laser measurement, computer- aided measurement, machine vision). | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
3 | 7 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 15% | 40% |
MDP387s | Metrology | 3 CH | |||||||||
Prerequisites | ( MDP281s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 0 Hours | 3 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
International system of units, Theory of measurements, Instrument classification, Types of magnification (mechanical, electrical, optical, pneumatic), Fits, Tolerances and limit gauges, Simple measuring Instruments (Vernier, micrometres, dial gauges, angle gauges, protractors, sine bar, sensitive level), Comparators, Measuring machines, Errors and calibration of measuring equipment, Indirect measurements, Screw thread and gear measurements, Surface roughness measurements (2D and 3D measurement), Static tests for machine tools, Advanced measuring techniques (laser measurement, computer- aided measurement, machine vision). | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MDP481 | Design of Tools & Production Facilities | 3 CH | |||||||||
Prerequisites | ( MDP382 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Jigs and Fixture: Advantages of jigs and fixtures, Principles of location, Types of locators, over determined location, principles of clamping, types of clamping, calculations of clamping forces, Design of drilling jigs, indexing jigs, milling fixtures, indexing table, single and multiple pieces’ fixtures, turning fixtures, welding fixture, and assembly fixture, Manufacturing of jigs and fixture, Economy of jigs and fixtures. Cutting tools: Modern cutting tool materials, Design and manufacturing of turning form tools, form relieved milling cutters, drilling tools and broaching tools. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP481s | Design of Tools & Production Facilities | 3 CH | |||||||||
Prerequisites | ( MDP382s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Jigs and Fixture: Advantages of jigs and fixtures, Principles of location, Types of locators, over determined location, principles of clamping, types of clamping, calculations of clamping forces, Design of drilling jigs, indexing jigs, milling fixtures, indexing table, single and multiple pieces’ fixtures, turning fixtures, welding fixture, and assembly fixture, Manufacturing of jigs and fixture, Economy of jigs and fixtures. Cutting tools: Modern cutting tool materials, Design and manufacturing of turning form tools, form relieved milling cutters, drilling tools and broaching tools. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
5 | 2 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP482 | Metrology & Measuring Instruments | 4 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 5 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Measuring Instruments: International system of units and standards, types of instrument magnification (mechanical, optical, electric, digital and pneumatic), measuring signals; static and dynamic response; design of limit gauges, simple measuring instruments, measuring instruments components; kinematics, comparators, measuring machines, CMM, advanced measuring techniques; computer vision, laser measurement, Nano measurement. Metrology: Linear measurement, angular measurement, form measurement, screw thread and gear measurement, geometric errors; straightness, flatness, roundness, squareness, alignment, parallelism and surface roughness measurement. Static tests for machine tools. Using CMM and advanced techniques in measurements. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP482s | Metrology & Measuring Instruments | 4 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 0 Hours | 5 Hours | |||||||||
Required SWL | 200 | Equivalent ECTS | 8 | ||||||||
Course Content | |||||||||||
Measuring Instruments: International system of units and standards, types of instrument magnification (mechanical, optical, electric, digital and pneumatic), measuring signals; static and dynamic response; design of limit gauges, simple measuring instruments, measuring instruments components; kinematics, comparators, measuring machines, CMM, advanced measuring techniques; computer vision, laser measurement, Nano measurement. Metrology: Linear measurement, angular measurement, form measurement, screw thread and gear measurement, geometric errors; straightness, flatness, roundness, squareness, alignment, parallelism and surface roughness measurement. Static tests for machine tools. Using CMM and advanced techniques in measurements. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 15% | 40% |
MDP483 | Computerized Numerical Controlled Machines | 2 CH | |||||||||
Prerequisites | ( MDP382 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Components of CNC machines; mechanical parts, sensors and transducers, limit switch, speed drive and control, operating of CNC machine tools; mode selection, cycle selection, dry run, reference datum; Programming of CNC; manual programming, using fixed cycles and subroutines; Fanuc, fagor, sinumeric and heidenihien Controls, Computer aided Programming. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP483s | Computerized Numerical Controlled Machines | 2 CH | |||||||||
Prerequisites | ( MDP382s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 100 | Equivalent ECTS | 4 | ||||||||
Course Content | |||||||||||
Components of CNC machines; mechanical parts, sensors and transducers, limit switch, speed drive and control, operating of CNC machine tools; mode selection, cycle selection, dry run, reference datum; Programming of CNC; manual programming, using fixed cycles and subroutines; Fanuc, fagor, sinumeric and heidenihien Controls, Computer aided Programming. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP484 | Product Life Cycle Management | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Benefits, development process, Phases of product lifecycle; conceive, design, realize, service; concurrent engineering workflow, bottom up design, to down design, pyramid of production systems; Product Lifecycle Management, Sustainable development, Quality and Environmental Assurance of Product Development, Life cycle analysis, Product Data Management and CAD, Design for disassembly, Product recovery cycle, PLM integration; case studies. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP484s | Product Life Cycle Management | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Benefits, development process, Phases of product lifecycle; conceive, design, realize, service; concurrent engineering workflow, bottom up design, to down design, pyramid of production systems; Product Lifecycle Management, Sustainable development, Quality and Environmental Assurance of Product Development, Life cycle analysis, Product Data Management and CAD, Design for disassembly, Product recovery cycle, PLM integration; case studies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP485 | Advanced Topics in CNC Machine Tools | 3 CH | |||||||||
Prerequisites | ( MDP483 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Micro scale products; micro system platforms, scaling laws, micro manufacturing techniques, micro machining, micro forming, photochemical machining, laser machining and joining, metrology and characterization, shape variation in micro manufacturing, lamina metrology, additive manufacturing, micro mechanical assembly, handling for micro manufacturing, sustainability of micro machining technologies. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP485s | Advanced Topics in CNC Machine Tools | 3 CH | |||||||||
Prerequisites | ( MDP483s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Micro scale products; micro system platforms, scaling laws, micro manufacturing techniques, micro machining, micro forming, photochemical machining, laser machining and joining, metrology and characterization, shape variation in micro manufacturing, lamina metrology, additive manufacturing, micro mechanical assembly, handling for micro manufacturing, sustainability of micro machining technologies. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MDP486 | Selected Topics in Manufacturing | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Selected topics in recent directions and advanced manufacturing techniques. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP486s | Selected Topics in Manufacturing | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Selected topics in recent directions and advanced manufacturing techniques. An introduction to the basic principles of polymer processing, mixing, extrusion (single and twin-screw extruders, foils, plates, profiles, blow forming), injection moulding, reactive processing, injection moulding-related processes, decorative moulding, extrusion and injection blow moulding, compression moulding, thermoforming, coating … etc. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MDP487 | Computer Integrated Manufacturing | 3 CH | |||||||||
Prerequisites | ( MDP483 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction, Computer aided design (CAD) systems, computer aided graphical modelling, Cad database, computer aided manufacturing (Cam) systems, computer aided process planning (CAPP) systems, robotics systems, group technology and cellular manufacturing systems, automated material handling systems, automated inspection systems, flexible manufacturing systems (FMS) | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP487s | Computer Integrated Manufacturing | 3 CH | |||||||||
Prerequisites | ( MDP483s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction, Computer aided design (CAD) systems, computer aided graphical modelling, Cad database, computer aided manufacturing (Cam) systems, computer aided process planning (CAPP) systems, robotics systems, group technology and cellular manufacturing systems, automated material handling systems, automated inspection systems, flexible manufacturing systems (FMS) | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP488 | Advanced Manufacturing Technology | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Non-Conventional Machining: ECM, EDM, WEDM, PCM, USM, WJM, LBM, PBM, Bio Machining, Hybrid Machining ... etc. Additive Manufacturing Processes: Stereo Lithography, Selective Laser Sintering, Fused Deposition Modelling, Laminated Object Manufacturing ... etc. Micro manufacturing: Micro scale products, micro system platforms, scaling laws, micro manufacturing techniques, handling for micro machining technologies | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP488s | Advanced Manufacturing Technology | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Non-Conventional Machining: ECM, EDM, WEDM, PCM, USM, WJM, LBM, PBM, Bio Machining, Hybrid Machining ... etc. Additive Manufacturing Processes: Stereo Lithography, Selective Laser Sintering, Fused Deposition Modelling, Laminated Object Manufacturing ... etc. Micro manufacturing: Micro scale products, micro system platforms, scaling laws, micro manufacturing techniques, handling for micro machining technologies | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP489 | Selected Topics in Forming | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Selected topics in recent directions and advanced forming techniques. High energy rate forming, electro- hydraulic, electromagnetic, Dynapak, Petro Forge. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
15% | 25% | 10% | 40% |
MDP489s | Selected Topics in Forming | 3 CH | |||||||||
Prerequisites | |||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 1 Hour | 2 Hours | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Selected topics in recent directions and advanced forming techniques. High energy rate forming, electro- hydraulic, electromagnetic, Dynapak, Petro Forge. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Design and Production Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
60% | 0% | 0% | 40% |
MDP490 | Die Design | 3 CH | |||||||||
Prerequisites | ( MDP281 ) AND ( MDP211 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 3 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Design of sheet metal of dies (single, compound, combination and progressive dies), Shearing (blanking and piercing), Bending (U- and V-bending), Deep drawing of cylindrical cup with and without flanges, Quadratic and rectangular shapes, Ironing. Design of forming dies. Parts of different types of dies and their materials and functions. The life and cost of different types of dies in terms of number of produced items. The capacity of different machines based on the utilized die. Manufacturing of dies. Plastic Moulding: Injection moulds: Tolerances in Mould and Part Design. Mould Steels, Mould Bases, Mould Layout, Ejection, Cooling, Gating, Hot Runners, Venting. Blow moulding processes, Materials, Primary equipment, Mould design and Auxiliary equipment. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
5 | 9 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP490s | Die Design | 3 CH | |||||||||
Prerequisites | ( MDP281s ) AND ( MDP211s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 3 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Design of sheet metal of dies (single, compound, combination and progressive dies), Shearing (blanking and piercing), Bending (U- and V-bending), Deep drawing of cylindrical cup with and without flanges, Quadratic and rectangular shapes, Ironing. Design of forming dies. Parts of different types of dies and their materials and functions. The life and cost of different types of dies in terms of number of produced items. The capacity of different machines based on the utilized die. Manufacturing of dies. Plastic Moulding: Injection moulds: Tolerances in Mould and Part Design. Mould Steels, Mould Bases, Mould Layout, Ejection, Cooling, Gating, Hot Runners, Venting. Blow moulding processes, Materials, Primary equipment, Mould design and Auxiliary equipment. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP491 | Design of Jigs and Fixtures | 3 CH | |||||||||
Prerequisites | ( MDP211 ) AND ( MDP385 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Advantages of jigs and fixtures, principles of location, types of locators, over-determined location, principles of clamping, design procedures, drilling jigs, indexing jigs, milling fixtures, turning fixtures, welding and assembly fixtures. Design and manufacturing of cutting form tools. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP491s | Design of Jigs and Fixtures | 2 CH | |||||||||
Prerequisites | ( MDP211s ) AND ( MDP385s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Advantages of jigs and fixtures, principles of location, types of locators, over-determined location, principles of clamping, design procedures, drilling jigs, indexing jigs, milling fixtures, turning fixtures, welding and assembly fixtures. Design and manufacturing of cutting form tools. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP492 | Advanced Manufacturing Systems | 3 CH | |||||||||
Prerequisites | ( MDP387 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Addressing the problems facing industry regarding the automated systems such that of automatic storing and retrieving, integrated manufacturing systems, application of conveyors in industry, integration of CNC machinery within the FMS, collective control of machinery and automated manufacturing systems. The students will be aware with major cutting-edge technologies of production automation and material handling, and how these technologies are used to construct modern manufacturing systems. Material Transport Systems; Storage Systems; Automatic Data Capture; Group Technology and Cellular Manufacturing; Flexible Manufacturing Systems; Transfer Lines and Similar Automated Manufacturing Systems; Automated Assembly Systems; Process Planning and Concurrent Engineering; Production Planning and Control Systems and Agile Manufacturing. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP492s | Advanced Manufacturing Systems | 3 CH | |||||||||
Prerequisites | ( MDP387s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 1 Hour | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Addressing the problems facing industry regarding the automated systems such that of automatic storing and retrieving, integrated manufacturing systems, application of conveyors in industry, integration of CNC machinery within the FMS, collective control of machinery and automated manufacturing systems. The students will be aware with major cutting-edge technologies of production automation and material handling, and how these technologies are used to construct modern manufacturing systems. Material Transport Systems; Storage Systems; Automatic Data Capture; Group Technology and Cellular Manufacturing; Flexible Manufacturing Systems; Transfer Lines and Similar Automated Manufacturing Systems; Automated Assembly Systems; Process Planning and Concurrent Engineering; Production Planning and Control Systems and Agile Manufacturing. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP493 | Additive Manufacturing | 3 CH | |||||||||
Prerequisites | ( MDP462 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Additive Manufacturing (AM) is driving a paradigm shift in design and manufacturing. Provides a comprehensive overview of AM, from process physics and material chemistry to process and technology development. Explores new engineering and product design degrees of freedom enabled by AM. Topics include fundamentals of polymer, metal and composite AM processes; process capabilities such as rate and resolution; material properties and their dependence on material characteristics, process parameters and machine designs; existing and new applications of AM; and a perspective on current and future technical challenges in AM. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Manufacturing Engineering |
4 | ||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
30% | 25% | 0% | 40% |
MDP493s | Additive Manufacturing | 3 CH | |||||||||
Prerequisites | ( MDP462s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
2 Hours | 2 Hours | 0 Hours | |||||||||
Required SWL | 150 | Equivalent ECTS | 6 | ||||||||
Course Content | |||||||||||
Additive Manufacturing (AM) is driving a paradigm shift in design and manufacturing. Provides a comprehensive overview of AM, from process physics and material chemistry to process and technology development. Explores new engineering and product design degrees of freedom enabled by AM. Topics include fundamentals of polymer, metal and composite AM processes; process capabilities such as rate and resolution; material properties and their dependence on material characteristics, process parameters and machine designs; existing and new applications of AM; and a perspective on current and future technical challenges in AM. | |||||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
35% | 25% | 0% | 40% |
MDP494 | Advanced Manufacturing Technology & Prototyping | 3 CH | |||||||||
Prerequisites | ( MDP181 OR MDP183 ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to advanced manufacturing including the working principles and applications of Computer Aided Manufacturing (CAM), CAD/CAM, Computer Integrated Manufacturing (CIM), Computer Numerical Control (CNC), unconventional machining (chemical machining (ECM), electric discharge machining (EDM), wire cut machining, abrasive jet, ultrasonic machining, electron beam machining, etc.). Digital manufacturing processes, rapid prototyping techniques and tools: 3D printing, 3D scanning. Stereo Litho-graphy, laser cutting, object printing, thermo-jet wax printing. Cleanroom technology in manufacturing and production process. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechatronics Engineering and Automation |
5 | 1 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
20% | 25% | 10% | 40% |
MDP494s | Advanced Manufacturing Technology & Prototyping | 3 CH | |||||||||
Prerequisites | ( MDP181s OR MDP183s ) | ||||||||||
Number of weekly Contact Hours | |||||||||||
Lecture | Tutorial | Laboratory | |||||||||
3 Hours | 1 Hour | 1 Hour | |||||||||
Required SWL | 125 | Equivalent ECTS | 5 | ||||||||
Course Content | |||||||||||
Introduction to advanced manufacturing including the working principles and applications of Computer Aided Manufacturing (CAM), CAD/CAM, Computer Integrated Manufacturing (CIM), Computer Numerical Control (CNC), unconventional machining (chemical machining (ECM), electric discharge machining (EDM), wire cut machining, abrasive jet, ultrasonic machining, electron beam machining, etc.). Digital manufacturing processes, rapid prototyping techniques and tools: 3D printing, 3D scanning. Stereo Litho-graphy, laser cutting, object printing, thermo-jet wax printing. Cleanroom technology in manufacturing and production process. | |||||||||||
Used in Program / Level | |||||||||||
Program Name or requirement | Study Level | Semester | |||||||||
Mechatronics Engineering |
4 | 8 | |||||||||
Assessment Criteria | |||||||||||
Student Activities | Mid-Term Exam | Oral/Practical | Final Exam | ||||||||
25% | 25% | 10% | 40% |