ECTS - Rapid Prototyping
Rapid Prototyping (MFGE405) Course Detail
Course Name | Course Code | Season | Lecture Hours | Application Hours | Lab Hours | Credit | ECTS |
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Rapid Prototyping | MFGE405 | Area Elective | 3 | 0 | 0 | 3 | 5 |
Pre-requisite Course(s) |
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N/A |
Course Language | English |
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Course Type | Elective Courses |
Course Level | Bachelor’s Degree (First Cycle) |
Mode of Delivery | Face To Face |
Learning and Teaching Strategies | Lecture, Drill and Practice. |
Course Lecturer(s) |
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Course Objectives | Participants will study topics fundamental to rapid prototyping and automated fabrication, including the generation of suitable CAD models, current rapid prototyping fabrication technologies, their underlying material science, the use of secondary processing, and the impact of these technologies on society. The rapid prototyping process will be illustrated by the actual design and fabrication of a part. |
Course Learning Outcomes |
The students who succeeded in this course;
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Course Content | Rapid prototyping technologies, CAD models suitable for automated fabrication, secondary processing, additive manufacturing technologies, stereolithography, fused deposition modeling, laminated object manufacturing, selective laser sintering, direct metal laser sintering, casting processes for rapid prototyping, investment casting, rapid tooling, reverse engineering. |
Weekly Subjects and Releated Preparation Studies
Week | Subjects | Preparation |
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1 | Overview of rapid prototyping and automated fabrication technologies • What is a prototype? • Why make a prototype? • What is automated fabrication? • History of numerical control • Process planning; manual, variant, generative | Chapter 1 |
2 | Introduction to injection molding • Introduction to injection molding • Design for injection molding • Selecting materials • UL standards | Chapter 2 |
3 | Rapid prototyping technologies • Machine tool motion • History of layered manufacturing • Stereolithography • Solid ground curing • Selective laser sintering • Fused deposition modeling • Laminated object manufacturing • Other systems | Chapter 3 |
4 | Rapid prototyping technologies • Machine tool motion • History of layered manufacturing • Stereolithography • Solid ground curing • Selective laser sintering • Fused deposition modeling • Laminated object manufacturing • Other systems | Chapter 4 |
5 | The underlying material science • Photopolymers • Thermoplastics • Powders | Chapter 5 |
6 | The underlying material science • Photopolymers • Thermoplastics • Powders | Chapter 6 |
7 | Generating CAD models suitable for automated fabrication • The .STL file format • Repairing CAD models • Adding support structures • Model slicing | Chapter 7 |
8 | Generating CAD models suitable for automated fabrication • The .STL file format • Repairing CAD models • Adding support structures • Model slicing | Chapter 8 |
9 | Secondary processing • RTV silicone rubber molds • Investment casting • Improving the quality of prototyping • Improving the productivity in manufacturing • Medical applications | Chapter 7 |
10 | Secondary processing • RTV silicone rubber molds • Investment casting • Improving the quality of prototyping • Improving the productivity in manufacturing • Medical applications | Chapter 8 |
11 | Secondary processing • RTV silicone rubber molds • Investment casting • Improving the quality of prototyping • Improving the productivity in manufacturing • Medical applications | Chapter 11 |
12 | Secondary processing • RTV silicone rubber molds • Investment casting • Improving the quality of prototyping • Improving the productivity in manufacturing • Medical applications | Chapter 12 |
13 | The future • Remote manufacturing on demand • Ongoing research activities • How can these technologies be improved? | Chapter 13 |
14 | The future • Remote manufacturing on demand • Ongoing research activities • How can these technologies be improved? | Chapter 14 |
15 | Final exam period | All chapters |
16 | Final exam period | All chapters |
Sources
Course Book | 1. Rafiq Noorani, Rapid Prototyping: Principles and Applications, John Wiley & Sons, Inc., 2006, ISBN 0-471-73001-7 |
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Other Sources | 2. Ian Gibson (ed.), Advanced Manufacturing Technology for Medical Applications, John Wiley & Sons, Ltd., 2005, ISBN 0-470-01688-4 |
Evaluation System
Requirements | Number | Percentage of Grade |
---|---|---|
Attendance/Participation | 1 | 15 |
Laboratory | 1 | 25 |
Application | - | - |
Field Work | - | - |
Special Course Internship | - | - |
Quizzes/Studio Critics | 5 | 5 |
Homework Assignments | 6 | 10 |
Presentation | - | - |
Project | - | - |
Report | - | - |
Seminar | - | - |
Midterms Exams/Midterms Jury | 1 | 20 |
Final Exam/Final Jury | 1 | 25 |
Toplam | 15 | 100 |
Percentage of Semester Work | 75 |
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Percentage of Final Work | 25 |
Total | 100 |
Course Category
Core Courses | X |
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Major Area Courses | |
Supportive Courses | |
Media and Managment Skills Courses | |
Transferable Skill Courses |
The Relation Between Course Learning Competencies and Program Qualifications
# | Program Qualifications / Competencies | Level of Contribution | ||||
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1 | 2 | 3 | 4 | 5 | ||
1 | Adequate knowledge of mathematics, physical sciences and the subjects specific to chemical engineering disciplines; the ability to apply theoretical and practical knowledge of these areas in the solution of complex engineering problems. | |||||
2 | The ability to define, formulate, and solve complex engineering problems; the ability to select and apply proper analysis and modeling methods for this purpose. | |||||
3 | The ability to design a complex system, process, device or product under realistic constraints and conditions in such a way as to meet the specific requirements; the ability to apply modern design methods for this purpose. | |||||
4 | The ability to select, and use modern techniques and tools needed to analyze and solve complex problems encountered in chemical engineering practices; the ability to use information technologies effectively. | |||||
5 | The ability to design experiments, conduct experiments, gather data, and analyze and interpret results for investigating complex engineering problems or research areas specific to engineering disciplines. | |||||
6 | The ability to work efficiently in inter-, intra-, and multi-disciplinary teams; the ability to work individually. | |||||
7 | Ability to communicate effectively in Turkish, both in writing and in writing; at least one foreign language knowledge; ability to write reports and understand written reports, to prepare design and production reports, to make presentations, to give clear and understandable instructions. | |||||
8 | Recognition of the need for lifelong learning; the ability to access information, follow developments in science and technology, and adapt and excel oneself continuously. | |||||
9 | Acting in conformity with the ethical principles; professional and ethical responsibility and knowledge of the standards employed in chemical engineering applications. | |||||
10 | Knowledge of business practices such as project management, risk management, and change management; awareness of entrepreneurship and innovation; knowledge of sustainable development. | |||||
11 | Knowledge of the global and social effects of chemical engineering practices on health, environment, and safety issues, and knowledge of the contemporary issues in engineering areas; awareness of the possible legal consequences of engineering practices. |
ECTS/Workload Table
Activities | Number | Duration (Hours) | Total Workload |
---|---|---|---|
Course Hours (Including Exam Week: 16 x Total Hours) | 16 | 4 | 64 |
Laboratory | |||
Application | |||
Special Course Internship | |||
Field Work | |||
Study Hours Out of Class | 16 | 3 | 48 |
Presentation/Seminar Prepration | |||
Project | |||
Report | |||
Homework Assignments | 6 | 3 | 18 |
Quizzes/Studio Critics | |||
Prepration of Midterm Exams/Midterm Jury | 2 | 2 | 4 |
Prepration of Final Exams/Final Jury | 1 | 3 | 3 |
Total Workload | 137 |