Direct Pellet Three-Dimensional Printing of Polybutylene Adipate-co-Terephthalate for a Greener Future
Abstract
:1. Introduction
2. Experimental Procedures
2.1. Material
2.2. Printing Process
2.3. Dynamic Mechanical Thermal Analysis
2.4. Mechanical Properties
2.5. Microstructure
2.6. Compressive and Energy-Absorption Behavior
2.7. Ability to Maintain Shape
3. Results and Discussion
3.1. Dynamic Mechanical Thermal Analysis
3.2. Mechanical Properties
3.3. Microstructure
3.4. Energy Absorption and Compressive Behavior
3.5. Ability to Maintain Shape
3.6. Advantages and Future of Direct Pellet-Based Printing
4. Conclusions
- The dynamic mechanical thermal analysis (DMTA) revealed that PBAT undergoes a transition from a glassy state to a rubbery state at a specific temperature (about −25 °C). This characteristic, along with its storage modulus and tan δ values, indicates that PBAT possesses elastomeric and soft properties at room temperature, making it suitable for flexible and resilient applications and hard to 3D print with conventional filament-based processes;
- The mechanical properties of the printed PBAT specimens were influenced by the nozzle temperature. Higher nozzle temperatures resulted in improved mechanical properties, including increased elongation at break and tensile strength. The sample printed at the highest nozzle temperature of 200 °C exhibited the best performance, with a remarkable elongation of 1379% and a tensile strength of 7.5 MPa;
- The 3D printed PBAT structures showed promising energy-absorption behavior. The specimens with 60% infill density demonstrated higher compressive strength (1338 KPa) and energy absorption compared with those with 40% infill density (1306 KPa). This suggests that PBAT has the potential to be utilized in applications where impact resistance and energy absorption are crucial;
- The SEM images showed that, with the increase in printing temperature, the quality of the PBAT printed parts improved significantly, in a way; for the sample printed at 160 °C, the microholes and weak adhesion between the layers are quite clear. meanwhile, the volume of microholes decreased with the increase in temperature up to 180 °C, and for the sample printed at 200 °C, the highest print quality was achieved and it was difficult to find microholes or even a layered structure;
- Overall, this study demonstrates the potential of PBAT as a standalone material for 3D printing applications, showcasing its unique properties, printing feasibility, and desirable mechanical performance. Further research and development in this area could contribute to the advancement of sustainable and eco-friendly 3D printing practices.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Nozzle temperature (°C) | 160–180–200 |
Nozzle diameter (mm) | 0.6 |
Printing speed (mm/min) | 300 |
Layer height (mm) | 0.4 |
Raster angles (°) | 0/90 |
Infill density (%) | 40, 60, and 100 |
Shell number | 2 |
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Karimi, A.; Rahmatabadi, D.; Baghani, M. Direct Pellet Three-Dimensional Printing of Polybutylene Adipate-co-Terephthalate for a Greener Future. Polymers 2024, 16, 267. https://doi.org/10.3390/polym16020267
Karimi A, Rahmatabadi D, Baghani M. Direct Pellet Three-Dimensional Printing of Polybutylene Adipate-co-Terephthalate for a Greener Future. Polymers. 2024; 16(2):267. https://doi.org/10.3390/polym16020267
Chicago/Turabian StyleKarimi, Armin, Davood Rahmatabadi, and Mostafa Baghani. 2024. "Direct Pellet Three-Dimensional Printing of Polybutylene Adipate-co-Terephthalate for a Greener Future" Polymers 16, no. 2: 267. https://doi.org/10.3390/polym16020267
APA StyleKarimi, A., Rahmatabadi, D., & Baghani, M. (2024). Direct Pellet Three-Dimensional Printing of Polybutylene Adipate-co-Terephthalate for a Greener Future. Polymers, 16(2), 267. https://doi.org/10.3390/polym16020267