4D printing of magnetism-responsive shape-morphing polymers
4D printed magnetic actuators are widely sought after due to its high-tech capabilities and flexibility as a composite material, with the ability to transform and eliminate excess manufacturing processes from the current norm, and potentially serve as a better candidate for a product. Challenges tha...
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Nanyang Technological University
2024
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sg-ntu-dr.10356-1778402024-05-31T09:05:14Z 4D printing of magnetism-responsive shape-morphing polymers Liew, Marcus Guan Wen Zhou Kun School of Mechanical and Aerospace Engineering kzhou@ntu.edu.sg Engineering Additive manufacturing 4D printing 4D printed magnetic actuators are widely sought after due to its high-tech capabilities and flexibility as a composite material, with the ability to transform and eliminate excess manufacturing processes from the current norm, and potentially serve as a better candidate for a product. Challenges that arise from printing such product include its material limitations in terms of mechanical properties and printability, complexity in design, precise in dimensions and the future scalability in terms of additive manufacturing. The research gap for this report includes the processing of materials, study on the performance and reliability of such materials, control mechanisms and potential future applications. Under methodology, a variety of methods and procedures are used, such as, ink preparation of the composite material, setting of printing parameters of the machine, magnetizing the product with an impulse magnetizer to study the effects of magnetic fields to the material, and the material’s characteristics by undergoing different types of characterization tests. Results and discussions will closely monitor the characterization of the ink and both mechanical and thermal properties will be recorded. Microscopy test will conclude the ink composite’s size of magnetic NdFeB microparticles and the presence of such on the surface, where an evenly spread out is the ideal case. In conclusion, key properties such as phase transition temperatures and shear-thinning behaviour were identified using DSC and rheological analysis. SEM imaging of NdFeB microparticles revealed size variations which affects mesogen alignment and thermal actuation. Despite agglomeration impacts mechanical properties, composite product of the LCE/NdFeB ink composite exhibited promising stimuli-responsive behaviour, particularly in thermal actuation. Research provides valuable insights into formulating viscoelastic nematic inks and developing advanced composites. For recommendations, to improve the even distribution of NdFeB particles, further optimization of DIW printing parameters is necessary, including ink viscosity, extrusion pressure, printing speed, and nozzle temperature. Future work should focus on magnetizing the printed LCE composite films to align the magnetic domains of NdFeB, enabling controllable shape-changing behaviours and part mating. Bachelor's degree 2024-05-31T09:05:14Z 2024-05-31T09:05:14Z 2024 Final Year Project (FYP) Liew, M. G. W. (2024). 4D printing of magnetism-responsive shape-morphing polymers. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/177840 https://hdl.handle.net/10356/177840 en application/pdf Nanyang Technological University |
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Engineering Additive manufacturing 4D printing Liew, Marcus Guan Wen 4D printing of magnetism-responsive shape-morphing polymers |
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4D printed magnetic actuators are widely sought after due to its high-tech capabilities and flexibility as a composite material, with the ability to transform and eliminate excess manufacturing processes from the current norm, and potentially serve as a better candidate for a product. Challenges that arise from printing such product include its material limitations in terms of mechanical properties and printability, complexity in design, precise in dimensions and the future scalability in terms of additive manufacturing. The research gap for this report includes the processing of materials, study on the performance and reliability of such materials, control mechanisms and potential future applications.
Under methodology, a variety of methods and procedures are used, such as, ink preparation of the composite material, setting of printing parameters of the machine, magnetizing the product with an impulse magnetizer to study the effects of magnetic fields to the material, and the material’s characteristics by undergoing different types of characterization tests. Results and discussions will closely monitor the characterization of the ink and both mechanical and thermal properties will be recorded. Microscopy test will conclude the ink composite’s size of magnetic NdFeB microparticles and the presence of such on the surface, where an evenly spread out is the ideal case. In conclusion, key properties such as phase transition temperatures and shear-thinning behaviour were identified using DSC and rheological analysis. SEM imaging of NdFeB microparticles revealed size variations which affects mesogen alignment and thermal actuation. Despite agglomeration impacts mechanical properties, composite product of the LCE/NdFeB ink composite exhibited promising stimuli-responsive behaviour, particularly in thermal actuation. Research provides valuable insights into formulating viscoelastic nematic inks and developing advanced composites. For recommendations, to improve the even distribution of NdFeB particles, further optimization of DIW printing parameters is necessary, including ink viscosity, extrusion pressure, printing speed, and nozzle temperature. Future work should focus on magnetizing the printed LCE composite films to align the magnetic domains of NdFeB, enabling controllable shape-changing behaviours and part mating. |
| author2 |
Zhou Kun |
| author_facet |
Zhou Kun Liew, Marcus Guan Wen |
| format |
Final Year Project |
| author |
Liew, Marcus Guan Wen |
| author_sort |
Liew, Marcus Guan Wen |
| title |
4D printing of magnetism-responsive shape-morphing polymers |
| title_short |
4D printing of magnetism-responsive shape-morphing polymers |
| title_full |
4D printing of magnetism-responsive shape-morphing polymers |
| title_fullStr |
4D printing of magnetism-responsive shape-morphing polymers |
| title_full_unstemmed |
4D printing of magnetism-responsive shape-morphing polymers |
| title_sort |
4d printing of magnetism-responsive shape-morphing polymers |
| publisher |
Nanyang Technological University |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/177840 |
| _version_ |
1800916333152436224 |