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2025-10-09
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Copyright (c) 2025 Hayjaa Mohaisen Mousa, Ahmed Abdullah Hussein, Abdullah H. Maad , Nibras Jamal, Fadhil M. Abid, Nour Sabah Kadhim Jaber Hameed Hussain , Muntadher Kadhum Sultan
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Sustainable Synthesis and Characterization of Wood-Fiber Reinforced PLA for Additive Manufacturing Applications
Hayjaa Mohaisen Mousa
Department of Medicinal Chemistry, College of Pharmacy, Al-Turath University, Baghdad,10013, Iraq
Ahmed Abdullah Hussein
Department of Analytics Laboratories, Al-Farahidi University, Baghdad, 10111, Iraq
Abdullah H. Maad
Department of Pharmaceutics, College of Pharmacy, University of Al-Ameed, Karbala Governorate, 56001,Iraq
Nibras Jamal
Department of Pharmacology and Toxicology , College of Pharmacy, Al-Bayan University,Iraq
Fadhil M. Abid
Al-Hadi University College, Baghdad,10011, Iraq
Nour Sabah Kadhim
Department of sciences,Al-Manara College For Medical Sciences,Maysan, 62010, Iraq
Jaber Hameed Hussain
Department of Medical Laboratories Technology, Al-Nisour University College, Nisour Seq. Karkh, Baghdad, 10015, Iraq
Muntadher Kadhum Sultan
Department of Medical Laboratories Technology, Mazaya university college,Dhi Qar,21974,Iraq
DOI: https://doi.org/10.59429/ace.v8i4.5725
Keywords: Additive manufacturing; wood-fiber reinforced pla; biopolymer filaments; sustainable development goals (SDGs); fused deposition modeling (FDM); green manufacturing; resin-based components
Abstract
The rising demand for environmentally responsible manufacturing has intensified interest in biodegradable polymers for additive manufacturing (AM). Polylactic Acid (PLA), a bio-based thermoplastic, is widely utilized due to its renewability and ease of processing. However, its inherent brittleness, low thermal resistance, and limited mechanical strength restrict its suitability for structural or load-bearing applications. This study addresses these limitations by developing and characterizing wood fiber (WF)-reinforced PLA composites aimed at improving mechanical performance and sustainability in AM, particularly Fused Deposition Modeling (FDM). Although natural fiber-reinforced biopolymers have shown promise, prior research often neglects eco-friendly processing, cost-effective preparation, and systematic optimization of fiber content and printing conditions. To overcome these gaps, sustainable composite filaments were produced using solvent-free melt compounding and extrusion techniques. Standardized specimens were fabricated via FDM and subjected to tensile, flexural, and compressive testing to assess mechanical properties. A multi-criteria decision-making (MCDM) approach was further employed to optimize printing parameters, balancing strength, energy efficiency, and material utilization. Results demonstrate that PLA-WF composites exhibit significant property enhancements, with tensile and flexural strengths improving by ~18% and ~22%, respectively, compared to neat PLA. The addition of WF not only strengthens structural performance but also lowers cost and reduces environmental impact, while maintaining good printability and dimensional stability. These findings highlight the potential of PLA-WF composites as sustainable alternatives for functional AM components and align with multiple United Nations Sustainable Development Goals (SDGs), including SDG 9, SDG 12, SDG 13, and SDG 15.
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