1. komponenta

Lecture type	Total
Lectures	30
Laboratory exercises	15

* Load is given in academic hour (1 academic hour = 45 minutes)

Additive manufacturing in chemical engineering

Course teacher
Domagoj Vrsaljko

Course objective
Acquisition of basic and specific knowledge about additive manufacturing technologies, ie 3D printing.

Course implementation program
1. Overview of production technologies. Introduction to additive manufacturing technologies.
2. Basic principles of additive manufacturing.
3. Polymeric materials for additive manufacturing technologies.
4. Metallic materials for additive manufacturing technologies.
5. Ceramic materials for additive manufacturing technologies.
6. Review of additive manufacturing technologies for polymeric materials. An overview of additive manufacturing technologies for metallic materials. An overview of additive manufacturing technologies for other materials.
7. Use of 3D printers for stereolithography (SLA) production. Using a 3D printer for fused filament fabrication (FFF). Use of 3D printers for production by selective laser sintering (SLS).
8. Examples of applications of additive manufacturing in chemical engineering.
9. Modeling with CAD software 1.
10. Modeling with CAD software 2.
11. Independent model making.
12. Independent model making.
13. Transfer the file to the 3D printer software (Slicer).
14. Creating a product with a 3D printer.
15. Colloquium.

Developing general and specific student competencies
Adopting a foundation on materials. Acquisition of basic and specific knowledge about additive manufacturing technologies, ie 3D printing. Learning teamwork and gaining the ability to communicate orally and in writing with experts in this and related fields.

Student obligations in teaching and ways of their execution
Class attendance: lectures, computer exercises and laboratory exercises.

Teaching methods
Lectures, computer exercises and laboratory exercises.

Method of testing knowledge and taking exams
The knowledge test is conducted continuously during the teaching process through conversation.
Created a virtual model + 3D printing of the model and a written exam

Course learning outcomes
1. compare the possibilities and select the appropriate material for the target product taking into account the mechanical and chemical properties of the material and the product
2. compare possibilities and choose the optimal additive manufacturing technology for the target product
3. select the basic steps in additive manufacturing processes
4. create a basic virtual model of the target product
5. compare the possibilities and select the optimal detailed settings of the selected production process
6. compare the quality of the manufactured product and suggest procedures that will approach the target properties

Learning outcomes at the program level to which the course contributes
1. integrate scientific principles of materials science and engineering: structure, properties, processing and application of materials
3. identify problems in area of materials science and engineering
6. plan complex experiments involving use of laboratory equipment and instruments
10. select suitable methods and equipment in processing, characterization and application of materials, taking into account work safety
14. explain results of their work to non-experts, experts in other fields and international partners

1. compare the possibilities and select the appropriate material for the target product taking into account the mechanical and chemical properties of the material and the product
2. compare possibilities and choose the optimal additive manufacturing technology for the target product
3. select the basic steps in additive manufacturing processes
4. create a basic virtual model of the target product
5. compare the possibilities and select the optimal detailed settings of the selected production process
6. compare the quality of the manufactured product and suggest procedures that will approach the target properties

1. Predavanja u sklopu kolegija, D Vrsaljko,
2. Additive Manufacturing Technologies: Rapid Prototyping to Direct Digital Manufacturing, Ian Gibson, David W. Rosen, Brent Stucker,

Izborna grupa - Regular studij - Material Science and Engineering