Week |
Subject |
Related Preparation |
1) |
Basic concepts of engineering: Duties and responsibilities of engineers in general engineering ethics
|
- |
2) |
System Definition: Definition of a system and its surroundings, concepts of input and output
|
- |
3) |
Basic Scientific Units:
SI and British unit systems, unit conversions
|
- |
4) |
Transformation of Energy via a Block Diagram Approach:
Interaction of the sub-systems between each other, basic energy transformation processes
|
- |
5) |
Transformation of Energy via a Block Diagram Approach:
Basic Energy Transformation Processes
|
- |
6) |
Conventional Sources of Energy: Petroleum, natural gas, coal
|
- |
7) |
Alternative Sources of Energy: Hydrogen energy, fuel cells, nuclear energy
|
- |
8) |
Renewable Energy: Solar energy, wind energy, bio-energy
|
- |
9) |
The Role of Energy Systems Engineers in Today’s World and in the Future: The work scope of energy systems engineers, current and future trends in energy systems engineering
|
- |
10) |
Term Project Presentations |
The students should revise the lecture notes on the related topic of that particular day's presentation. |
11) |
Term Project Presentations |
The students should revise the lecture notes on the related topic of that particular day's presentation. |
12) |
Term Project Presentations |
The students should revise the lecture notes on the related topic of that particular day's presentation. |
13) |
Term Project Presentations |
The students should revise the lecture notes on the related topic of that particular day's presentation. |
14) |
Term Project Presentations |
The students should revise the lecture notes on the related topic of that particular day's presentation. |
15) |
Preparation for the final exam |
- |
16) |
Preparation for the final exam |
- |
|
Program Outcomes |
Level of Contribution |
1) |
Having the theoretical and practical knowledge proficiency in the discipline of industrial product design |
|
2) |
Applying professional knowledge to the fields of product, service and experience design development |
|
3) |
Understanding, using, interpreting and evaluating the design concepts, knowledge and language |
|
4) |
Knowing the research methods in the discipline of industrial product design, collecting information with these methods, interpreting and applying the collected knowledge |
|
5) |
Identifying the problems of industrial product design, evaluating the conditions and requirements of problems, producing proposals of solutions to them |
|
6) |
Developing the solutions with the consideration of social, cultural, environmental, economic and humanistic values; being sensitive to personal differences and ability levels |
|
7) |
Having the ability of communicating the knowledge about design concepts and solutions through written, oral and visual methods |
|
8) |
To identify and apply the relation among material, form giving, detailing, maintenance and manufacturing methods of design solutions |
|
9) |
Using the computer aided information and communication technologies for the expression of industrial product design solutions and applications |
|
10) |
Having the knowledge and methods in disciplines like management, engineering, psychology, ergonomics, visual communication which support the solutions of industrial product design; having the ability of searching, acquiring and using the knowledge that belong these disciplines when necessary. |
|
11) |
Using a foreign language to command the jargon of industrial product design and communicate with the colleagues from different cultures |
|
12) |
Following and evaluating the new topics and trends that industrial product design needs to integrate according to technological and scientific developments |
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