Carbon fiber and cobalt composites in the nanotechnology industry and the analysis of the new flexible structure, according to the CES EduPack method (CES Selector Grant).
Session
Integrated Design
Description
Carbon fiber and cobalt composites are advanced materials with wide applications in the nanotechnology industry due to their unique mechanical and physical properties. This study uses the CES EduPack (Granta CES Selector) method to generate and compare the structures of these composites. Through the analysis of stiffness, strength, density and cost data, the advantages and trade-offs of each material are identified. Carbon fiber composites stand out for their high stiffness and strength, but have a higher cost compared to cobalt composites, which offer greater flexibility and higher density. This detailed comparison provides a solid basis for the optimal selection of materials in specific applications, taking into account factors such as mechanical performance, weight and cost. The CES EduPack method facilitates this process, offering advanced tools for analysis and visualization of material data.
Keywords:
Composites, flexibility, cobalt, carbon fiber, methods, materials.
Proceedings Editor
Edmond Hajrizi
ISBN
978-9951-982-15-3
Location
UBT Kampus, Lipjan
Start Date
25-10-2024 9:00 AM
End Date
27-10-2024 6:00 PM
DOI
10.33107/ubt-ic.2024.227
Recommended Citation
Ostergllava, Nam and Ostergllava, Arenë, "Carbon fiber and cobalt composites in the nanotechnology industry and the analysis of the new flexible structure, according to the CES EduPack method (CES Selector Grant)." (2024). UBT International Conference. 8.
https://knowledgecenter.ubt-uni.net/conference/2024UBTIC/ID/8
Carbon fiber and cobalt composites in the nanotechnology industry and the analysis of the new flexible structure, according to the CES EduPack method (CES Selector Grant).
UBT Kampus, Lipjan
Carbon fiber and cobalt composites are advanced materials with wide applications in the nanotechnology industry due to their unique mechanical and physical properties. This study uses the CES EduPack (Granta CES Selector) method to generate and compare the structures of these composites. Through the analysis of stiffness, strength, density and cost data, the advantages and trade-offs of each material are identified. Carbon fiber composites stand out for their high stiffness and strength, but have a higher cost compared to cobalt composites, which offer greater flexibility and higher density. This detailed comparison provides a solid basis for the optimal selection of materials in specific applications, taking into account factors such as mechanical performance, weight and cost. The CES EduPack method facilitates this process, offering advanced tools for analysis and visualization of material data.