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Comparative study on selective laser sintering of aromatic and aliphatic thermoplastic polyurethanes: processability, microstructure, and mechanical properties

Singapore Centre for 3D Printing, School of Mechanical and Aerospace Engineering, Nanyang Technological University, 50 Nanyang Avenue, Singapore 639798, Singapore

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Wei Zhu

College of Mechanical and Vehicle Engineering, Hunan University, Changsha 410082, P. R. China

Wei Zhu is the co-first author.

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Suzhu Yu

Singapore Institute of Manufacturing Technology, 73 Nanyang Drive Singapore 637662, Singapore

Shenzhen Key Laboratory of Flexible Printed Electronics Technology, School of Materials Science and Engineering, Harbin Institute of Technology (Shenzhen), Shenzhen 518055, P. R. China

E-mail Address: szyu@hit.edu.cn

Corresponding author.

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Yujia Tian

Singapore Centre for 3D Printing, School of Mechanical and Aerospace Engineering, Nanyang Technological University, 50 Nanyang Avenue, Singapore 639798, Singapore

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Jun Wei

Shenzhen Key Laboratory of Flexible Printed Electronics Technology, School of Materials Science and Engineering, Harbin Institute of Technology (Shenzhen), Shenzhen 518055, P. R. China

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, and

Kun Zhou

Singapore Centre for 3D Printing, School of Mechanical and Aerospace Engineering, Nanyang Technological University, 50 Nanyang Avenue, Singapore 639798, Singapore

E-mail Address: kzhou@ntu.edu.sg

Corresponding author.

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https://doi.org/10.1142/S2424913022500023Cited by:4 (Source: Crossref)

Abstract

Selective laser sintering (SLS) of thermoplastic polyurethane (TPU) has attracted tremendous interest in producing prototypes and end-use parts for applications in mechanical energy absorption, biomedical scaffold, and wearable electronics because of the versatile properties of this material. This work aims to reveal the effects of the chemical structure on the SLS processability of TPU powders as well as the microstructure and mechanical properties of their SLS-printed parts. It was found that the aliphatic TPU exhibited better SLS processability and lower total porosity than the aromatic TPU because of its flexible polymer chains. In contrast, the aromatic TPU displayed higher tensile strength and mechanical energy absorption because of its rigid polymer chains and the increased intermolecular force. Pores in the SLS-printed parts were classified based on their morphological features, and their origins were investigated via X-ray computed tomography. This study provides guidance for the design, selection, and optimization of TPU powders for the SLS process according to different applications.

Keywords:

References

P. Parandoush and D. Lin. A review on additive manufacturing of polymer-fiber composites. Composite Structures 182, pp. 36–53, 2017. Crossref, Google Scholar
T. D. Ngo, A. Kashani, G. Imbalzano, K. T. Q. Nguyen and D. Hui. Additive manufacturing (3D printing): A review of materials, methods, applications and challenges. Composites Part B: Engineering 143, pp. 172–196, 2018. Crossref, Google Scholar
Y. Xie, S. Li, C. T. Wu, D. Lyu, C. Wang and D. Zeng. A generalized Bayesian regularization network approach on characterization of geometric defects in lattice structures for topology optimization in preliminary design of 3D printing. Computational Mechanics 69(5), pp. 1191–1212, 2022. Crossref, Google Scholar
S. C. Ligon, R. Liska, J. Stampfl, M. Gurr and R. Mülhaupt. Polymers for 3D printing and customized additive manufacturing. Chemical Reviews 117(15), pp. 10212–10290, 2017. Crossref, Google Scholar
A. Zhakeyev, P. Wang, L. Zhang, W. Shu, H. Wang and J. Xuan. Additive manufacturing: Unlocking the evolution of energy materials. Advanced Science 4(10), pp. 1700187-1–44, 2017. Crossref, Google Scholar
M. Wiese, S. Thiede and C. Herrmann. Rapid manufacturing of automotive polymer series parts: A systematic review of processes, materials and challenges. Additive Manufacturing 36, pp. 101582-1–13, 2020. Crossref, Google Scholar
S. Yuan, S. Li, J. Zhu and Y. Tang. Additive manufacturing of polymeric composites from material processing to structural design. Composites Part B: Engineering 219(April), pp. 108903-1–25, 2021. Google Scholar
C. Zhang, Y. Li, W. Kang, X. Liu and Q. Wang. Current advances and future perspectives of additive manufacturing for functional polymeric materials and devices. SusMat 1(1), pp. 127–147, 2021. Crossref, Google Scholar
S. Yuan, F. Shen, C. K. Chua and K. Zhou. Polymeric composites for powder-based additive manufacturing: Materials and applications. Progress in Polymer Science 91, pp. 141–168, 2019. Crossref, Google Scholar
C. A. Chatham, T. E. Long and C. B. Williams. A review of the process physics and material screening methods for polymer powder bed fusion additive manufacturing. Progress in Polymer Science 93, pp. 68–95, 2019. Crossref, Google Scholar
K. Plummer, M. Vasquez, C. Majewski and N. Hopkinson. Study into the recyclability of a thermoplastic polyurethane powder for use in laser sintering. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 226(7), pp. 1127–1135, 2012. Crossref, Google Scholar
Y. Zhuang, Y. Guo, J. Li, Y. Yu, K. Jiang, H. Zhang and S. Guo. Study on the forming and sensing properties of laser-sintered TPU/CNT composites for plantar pressure sensors. International Journal of Advanced Manufacturing Technology 112(7–8), pp. 2211–2222, 2021. Crossref, Google Scholar
Z. Li, Z. Wang, X. Gan, D. Fu, G. Fei and H. Xia. Selective laser sintering 3D printing: A way to construct 3D electrically conductive segregated network in polymer matrix. Macromolecular Materials and Engineering 302(11), pp. 1–10, 2017. Crossref, Google Scholar
X. Gan, J. Wang, Z. Wang, Z. Zheng, M. Lavorgna, A. Ronca, G. Fei and H. Xia. Simultaneous realization of conductive segregation network microstructure and minimal surface porous macrostructure by SLS 3D printing. Materials and Design 178, pp. 107874-1-10, 2019. Crossref, Google Scholar
L. J. Tan, W. Zhu and K. Zhou. Recent progress on polymer materials for additive manufacturing. Advanced Functional Materials 2003062(43), pp. 1–54, 2020. Google Scholar
J. G. Drobny, Handbook of Thermoplastic Elastomers, 2nd edn. (Elsevier, Amsterdam), 2014. Google Scholar
Y. He, D. Xie and X. Zhang. The structure, microphase-separated morphology, and property of polyurethanes and polyureas. Journal of Materials Science 49(21), pp. 7339–7352, 2014. Crossref, Google Scholar
S. Dadbakhsh, L. Verbelen, T. Vandeputte, D. Strobbe, P. Van Puyvelde and J. P. Kruth. Effect of powder size and shape on the SLS processability and mechanical properties of a TPU elastomer. Physics Procedia 83, pp. 971–980, 2016. Crossref, Google Scholar
T. Ziegler, J. H. Marquez, R. Jaeger and S. Phommahavong. Wear mechanisms and abrasion rates in selective laser sintering materials. Polymer Testing 67(March), pp. 545–550, 2018. Crossref, Google Scholar
L. Verbelen, S. Dadbakhsh, M. Van den Eynde, D. Strobbe, J. P. Kruth, B. Goderis and P. Van Puyvelde. Analysis of the material properties involved in laser sintering of thermoplastic polyurethane. Additive Manufacturing 15, pp. 12–19, 2017. Crossref, Google Scholar
R. Pan, L. Yang, L. Zheng, L. Hao, Y. Li, A. M. Bluell and D. E. Montgomery. Microscopic morphology, thermodynamic and mechanical properties of thermoplastic polyurethane fabricated by selective laser sintering. Materials Research Express 7(5), pp. 055301-1–11, 2020. Crossref, Google Scholar
T. Xu, W. Shen, X. Lin and Y. M. Xie. Mechanical properties of additively manufactured thermoplastic polyurethane (TPU) material affected by various processing parameters. Polymers 12(12), pp. 1–16, 2020. Crossref, Google Scholar
S. Yuan, F. Shen, J. Bai, C. K. Chua, J. Wei and K. Zhou. 3D soft auxetic lattice structures fabricated by selective laser sintering: TPU powder evaluation and process optimization. Materials & Design 120, pp. 317–327, 2017. Crossref, Google Scholar
S. Yuan, J. Li, X. Yao, J. Zhu, X. Gu, T. Gao, Y. Xu and W. Zhang. Intelligent optimization system for powder bed fusion of processable thermoplastics. Additive Manufacturing 34(March), pp. 101182-1–13, 2020. Google Scholar
A. Haryńska, J. Kucinska-Lipka, A. Sulowska, I. Gubanska, M. Kostrzewa and H. Janik. Medical-grade PCL based polyurethane system for FDM 3D printing — characterization and fabrication. Materials 12(6), pp. 887-1–18, 2019. Crossref, Google Scholar
D. Drummer, M. Medina-Hernández, M. Drexler and K. Wudy. Polymer powder production for laser melting through immiscible blends. Procedia Engineering 102, pp. 1918–1925, 2015. Crossref, Google Scholar
R. D. Goodridge, C. J. Tuck and R. J. M. Hague. Laser sintering of polyamides and other polymers. Progress in Materials Science 57(2), pp. 229–267, 2012. Crossref, Google Scholar
R. Kleijnen, M. Schmid and K. Wegener. Production and processing of a spherical polybutylene terephthalate powder for laser sintering. Applied Sciences 9(7), pp. 1308-1–17, 2019. Crossref, Google Scholar
S. Ziegelmeier, P. Christou, F. Wöllecke, C. Tuck, R. Goodridge, R. Hague, E. Krampe and E. Wintermantel. An experimental study into the effects of bulk and flow behaviour of laser sintering polymer powders on resulting part properties. Journal of Materials Processing Technology 215(1), pp. 239–250, 2015. Crossref, Google Scholar
R. M. Briber and E. L. Thomas. Investigation of two crystal forms in MDI/BDO-based polyurethanes. Journal of Macromolecular Science, Part B 22(4), pp. 509–528, 1983. Crossref, Google Scholar
T. K. Chen, J. Y. Chui and T. S. Shieh. Glass transition behaviors of a polyurethane hard segment based on 4,4 $'$ -diisocyanatodiphenylmethane and 1,4-butanediol and the calculation of microdomain composition. Macromolecules 30(17), pp. 5068–5074, 1997. Crossref, Google Scholar
D. Pedrazzoli and I. Manas-Zloczower. Understanding phase separation and morphology in thermoplastic polyurethanes nanocomposites. Polymer 90, pp. 256–263, 2016. Crossref, Google Scholar
D. Drummer, D. Rietzel and F. Kühnlein. Development of a characterization approach for the sintering behavior of new thermoplastics for selective laser sintering. Physics Procedia 5(PART 2), pp. 533–542, 2010. Crossref, Google Scholar
M. Vasquez, B. Haworth and N. Hopkinson. Methods for quantifying the stable sintering region in laser sintered polyamide-12. Polymer Engineering & Science 53(6), pp. 1230–1240, 2013. Crossref, Google Scholar
M. Vasquez, B. Haworth and N. Hopkinson. Optimum sintering region for laser sintered Nylon-12. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 225(12), pp. 2240–2248, 2011. Crossref, Google Scholar
L. Benedetti, B. Brulé, N. Decraemer, K. E. Evan and O. Ghita. Evaluation of particle coalescence and its implications in laser sintering. Powder Technology 342(11), pp. 917–928, 2019. Crossref, Google Scholar
H. Wadell. Volume, shape, and roundness of quartz particles. The Journal of Geology 43(3), pp. 250–280, 1935. Crossref, Google Scholar
B. R. Jennings. Particle size measurement: the equivalent spherical diameter. Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences 419(1856), pp. 137–149, 1988. Crossref, Google Scholar
R. Snell, S. Tammas-Williams, L. Chechik, A. Lyle, E. Hernández-Nava, C. Boig, G. Panoutsos and I. Todd. Methods for rapid pore classification in metal additive manufacturing. Jom 72(1), pp. 101–109, 2020. Crossref, Google Scholar
Z. Zhu and C. Majewski. Understanding pore formation and the effect on mechanical properties of High Speed Sintered polyamide-12 parts: A focus on energy input. Materials and Design 194, pp. 108937-1–16, 2020. Crossref, Google Scholar
M. Zhou, W. Zhu, S. Yu, Y. Tian and K. Zhou. Selective laser sintering of carbon nanotube-coated thermoplastic polyurethane: Mechanical, electrical, and piezoresistive properties. Composites Part C: Open Access 7, pp. 100212-1–12, 2022. Crossref, Google Scholar
S. Dupin, O. Lame, C. Barrès and J. Y. Charmeau. Microstructural origin of physical and mechanical properties of polyamide 12 processed by laser sintering. European Polymer Journal 48(9), pp. 1611–1621, 2012. Crossref, Google Scholar
C. P. Buckley, C. Prisacariu and C. Martin. Elasticity and inelasticity of thermoplastic polyurethane elastomers: Sensitivity to chemical and physical structure. Polymer 51(14), pp. 3213–3224, 2010. Crossref, Google Scholar