Fused Deposition Modelling Approach in Recycled Polypropylene/Aluminum Powder Composites for Sustainable Development

Manveer Rana, Mohit Kumar, Ranvijay Kumar

Abstract

Polypropylene (PP) is a versatile and widely used thermoplastic polymer that has found its way into various aspects from packaging materials and consumer products to automotive components and industrial applications. However, this widespread use of polypropylene also presents a significant challenge in the disposal of polypropylene waste and its durability aspects. So, the fused deposition modeling (FDM) technique arises as compiling outcomes for recycling discarded PP waste to create functional products. The properties of FDM components produced from recycled polypropylene (r-PP) are notably inferior to those of virgin PP FDM counterparts. Hence, it becomes imperative to comprehend the substantial alterations that r-PP undergoes during successive extrusion processes, including chain scission, alterations in viscosity, and reductions in breaking strength. The incorporation of additives has emerged as a promising solution to enhance the performance of r-PP. In this context, the present study explores the development of a novel composite material by blending r-PP with aluminum powder. The combination of these materials leverages the sustainability benefits of r-PP and the excellent thermal and mechanical properties of aluminum, making it a promising candidate for a wide range of applications. The tensile results show a significant increase in Young’s modulus for pre-heat treated composite specimen at 214 ℃ extrusion temperature. The SEM fractrographic analysis confirms the homogenized distribution after pre-heat treatments. XRD results analyzed the degree of crystallinity in the composite specimens.

Keywords

References

[1] S. C. Ligon, R. Liska, J. Stampfl, M. Gurr, and R. Mülhaupt, “Polymers for 3D printing and customized additive manufacturing,” Chemical Reviews, vol. 117, no. 15, pp. 10212–10290, 2017.

[2] S. S. Alghamdi, S. John, N. R. Choudhury, and N. K. Dutta, “Additive manufacturing of polymer materials: Progress, promise and challenges,” Polymers, vol. 13, no. 5, p. 753, 2021.

[3] L. J. Tan, W. Zhu, and K. Zhou, “Recent progress on polymer materials for additive manufacturing,” Advanced Functional Materials, vol. 30, no. 43, 2020, Art. no. 2003062.

[4] A. D. Mazurchevici, D. Nedelcu, and R. Popa, “Additive manufacturing of composite materials by FDM technology: A review,” Indian Journal of Engineering and Materials Sciences (IJEMS), 2020, doi: 10.56042/ijems.v27i2.45920.

[5] S. C. Daminabo, S. Goel, S. A. Grammatikos, H. Y. Nezhad, and V. K. Thakur, “Fused deposition modeling-based additive manufacturing (3D printing): Techniques for polymer material systems,” Materials Today Chemistry, vol. 16, 2020, Art. no. 100248.

[6] W. Abd-Elaziem, M. Khedr, A. E. Abd-Elaziem, M. M. A. Allah, A. A. Mousa, H. M. Yehia, and M. A. A. El-Baky, “Particle-reinforced polymer matrix composites (PMC) fabricated by 3D printing,” Journal of Inorganic and Organometallic Polymers and Materials, vol. 33, no. 12, pp. 3732–3749, 2023.

[7] M. Baechle-Clayton, E. Loos, M. Taheri, and H. Taheri, “Failures and flaws in fused deposition modeling (FDM) additively manufactured polymers and composites,” Journal of Composites Science, vol. 6, no.7, p. 202, 2022.

[8] S. Mani, A. Kasi, R. Guruswamy, K. B. Nilagiri Balasubramanian, and A. Pandian, “Effect of post-processing treatment on 3D-printed polylactic acid parts: Layer interfaces and mechanical properties,” International Journal of Materials Research, vol. 114, no. 10–11, pp. 999–1005, 2023.

[9] H. A. Maddah, “Polypropylene as a promising plastic: A review,” American Journal of Polymer Science, vol. 6, no. 1, pp. 1–11, 2016.

[10] O. S. Carneiro, A. F. Silva, and R. Gomes, “Fused deposition modeling with polypropylene,” Materials & Design, vol. 83, pp. 768–776, 2015.

[11] R. V. Moharir and S. Kumar, “Challenges associated with plastic waste disposal and allied microbial routes for its effective degradation: A comprehensive review,” Journal of Cleaner Production, vol. 208, pp. 65–76, 2019.

[12] N. Evode, S. A. Qamar, M. Bilal, D. Barceló, and H. M. Iqbal, “Plastic waste and its management strategies for environmental sustainability,” Case Studies in Chemical and Environmental Engineering, vol. 4, 2021, Art. no. 100142.

[13] M. Kumar, J. S. Saini, H. Bhunia, and S. R. Chowdhury, “Aging of bolted joints prepared from electron‐beam‐cured multiwalled carbon nanotube‐based nanocomposites with variable torques,” Polymer Composites, vol. 42, no. 8, pp. 4082–4104, 2021.

[14] M. Kumar, J. S. Saini, and H. Bhunia, “Performance of mechanical joints prepared from carbon-fiber-reinforced polymer nanocomposites under accelerated environmental aging,” Journal of Materials Engineering and Performance, vol. 29, pp. 7511–7525, 2020.

[15] R. Phiri, S. M. Rangappa, S. Siengchin, and D. Marinkovic, “Agro-waste natural fiber sample preparation techniques for bio-composites development: methodological insights,” Facta Universitatis, Series: Mechanical Engineering, vol. 21, no. 4, pp. 631–656, 2023.

[16] S. K. Palaniappan, M. K. Singh, S. M. Rangappa, and S. Siengchin, “Eco-friendly biocomposites: A step towards achieving sustainable development goals,” Composites, vol. 7, no. 12, pp. 1–3, 2023.

[17] I. Suyambulingam, S. M. Rangappa, and S. Siengchin, “Advanced materials and technologies for engineering applications,” Applied Science and Engineering Progress, vol. 16, no. 3, pp. 6760–6760, 2023, doi: 10.14416/j.asep.2023.01.008.

[18] Y. C. Jang, G. Lee, Y. Kwon, J. H. Lim, and J. H. Jeong, “Recycling and management practices of plastic packaging waste towards a circular economy in South Korea,” Resources, Conservation and Recycling, vol. 158, 2020, Art. no. 104798.

[19] S. Gharde and B. Kandasubramanian, “Mechanothermal and chemical recycling methodologies for the fibre reinforced plastic (FRP),” Environmental Technology & Innovation, vol. 14, 2019, Art. no. 100311.

[20] V. Mishra, S. Negi, and S. Kar, “FDM-based additive manufacturing of recycled thermoplastics and associated composites,” Journal of Material Cycles and Waste Management, vol. 25, no. 2, pp. 758–784, 2023.

[21] A. Al Rashid and M. Koc, “Additive manufacturing for sustainability and circular economy: Needs, challenges, and opportunities for 3D printing of recycled polymeric waste,” Materials Today Sustainability, 2023, Art. no. 100529.

[22] K. Chawla, J. Singh, and R. Singh, “On recyclability of thermosetting polymer and wood dust as reinforcement in secondary recycled ABS for nonstructural engineering applications,” Journal of Thermoplastic Composite Materials, vol. 35, no. 7, pp. 913–937, 2022.

[23] R. Singh, R. Kumar, S. Tiwari, S. Vishwakarma, S. Kakkar, V. Rajora, and S. Bhatoa, “On secondary recycling of ZrO₂-reinforced HDPE filament prepared from domestic waste for possible 3-D printing of bearings,” Journal of Thermoplastic Composite Materials, vol. 34, no. 9, pp. 1254–1272, 2021.

[24] P. Bedi, R. Singh, and I. P. S. Ahuja, “Effect of SiC/Al₂O₃ particle size reinforcement in recycled LDPE matrix on mechanical properties of FDM feed stock filament,” Virtual and Physical Prototyping, vol. 13, no. 4, pp. 246–254, 2018.

[25] M. Idrees, S. Jeelani, and V. Rangari, “Three-dimensional-printed sustainable biochar-recycled PET composites,” ACS Sustainable Chemistry & Engineering, vol. 6, no. 11, pp. 13940–13948, 2018.

[26] I. A. Carrete, P. A. Quiñonez, D. Bermudez, and D. A. Roberson, “Incorporating textile-derived cellulose fibers for the strengthening of recycled polyethylene terephthalate for 3D printing feedstock materials,” Journal of Polymers and the Environment, vol. 29, pp. 662–671, 2021.

[27] H. Junaedi, M. Baig, A. Dawood, E. Albahkali, and A. Almajid, “Effect of the matrix melt flow index and fillers on mechanical properties of polypropylene-based Composites,” Materials, vol. 15, no. 21, 2022, Art. no. 7568.

[28] M. R. Parida, S. Mohanty, M. Biswal, S. K. Nayak, and S. Rai, “Influence of aluminum trihydrate (ATH) particle size on mechanical, thermal, flame retardancy and combustion behavior of polypropylene composites,” Journal of Thermal Analysis and Calorimetry, vol. 148, no. 3, pp. 807–819, 2023.

[29] S. Siraj, A. H. Al-Marzouqi, M. Z. Iqbal, and W. Ahmed, “Impact of micro silica filler particle size on mechanical properties of polymeric based composite material,” Polymers, vol. 14, no. 22, 2022, Art. no. 4830.

[30] O. Meziane, A. Bensedira, and M. Guessoum, “Rheological, mechanical, and morphological behaviour of polypropylene composites reinforced with ultrafine kaolinite particles,” Matériaux & Techniques, vol. 112, no. 1, p. 105, 2024.

[31] E. D. S. B. Ferreira, C. B. B. Luna, E. M. Araujo, D. D. Siqueira, and R. M. R. Wellen, “Polypropylene/wood powder composites: Evaluation of PP viscosity in thermal, mechanical, thermomechanical, and morphological characters,” Journal of Thermoplastic Composite Materials, vol. 35, no. 1, pp. 71–92, 2022.

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DOI: 10.14416/j.asep.2024.07.009

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