Browsing by Author "Mohamed Shafeer, P.P."

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A short banana fiber—PLA filament for 3D printing: Development and characterization
(John Wiley and Sons Inc, 2025) Mohamed Shafeer, P.P.; Pitchaimani, J.; Doddamani, M.
This study aims to develop a 3D printable composite filament using short banana fiber and polylactic acid (PLA). The filament was acquired through a single screw extruder, employing various blending techniques. Various fiber loadings were examined, impacting PLA's mechanical, thermal, and printability properties. The results revealed altered mechanical characteristics, with reduced tensile and flexural properties compared with pure PLA. However, these values are at an acceptable level for non-structural applications. Compared with previous works, the filament developed in the present work is found out to be second strongest among the cellulose fiber-reinforced PLA filaments. 3D printing with the composite filament encountered no significant issues. A modified mixing method improved mechanical characteristics, although 3D-printed samples showed deteriorated mechanical characteristics due to poor interfacial bonding. This research introduces an environmentally viable strategy for advancing 3D printing technology by integrating banana fibers into PLA filament. The proposed strategy can be effectively utilized in making cellulose/PLA filaments for 3D printing applications. This innovative approach preserves PLA's natural biodegradability while carefully managing the integration of banana fibers and their potential effects on mechanical properties. Highlights: Fiber loading influences mechanical, with minimal impact on thermal properties. Solution casting improved fiber/matrix bonding and filler homogeneity. Plasticizing effect reduces the tensile strength. Modified mixing resulted in even filament diameter and improved tensile properties. © 2024 Society of Plastics Engineers.
Experimental investigation of embedded neck designs and core geometries for enhanced low-frequency sound absorption in 3D printed micro-perforated panels
(Elsevier Ltd, 2025) Mohamed Shafeer, P.P.; Pitchaimani, J.; Doddamani, M.
This study presents an experimental investigation into the acoustic performance enhancement of micro-perforated panel (MPP) based liners through structural modifications involving embedded necks and engineered core geometries. All samples were produced through fused deposition modeling with polylactic acid as the filament material. Sound absorption coefficients were measured using an impedance tube method (ASTM E1050) in a 50–1600 Hz frequency range. Initially, cylindrical necks of varying lengths were analyzed to assess the impact of neck extension on sound absorption, particularly in the low-frequency range. This was followed by evaluating non-cylindrical embedded neck profiles (converging, diverging, converging-diverging, and diverging-converging) for a fixed neck length. Then the effect of engineered core topologies, including square, hexagonal, re-entrant, and hybrid geometries, is studied on broadband absorption. Finally, selected core designs were combined with embedded necks to examine the synergetic effects. Incorporation of a cylindrical embedded neck results in shifting of peak absorption to lower frequency (328 Hz for 5 mm), with a weight reduction of 37.5 % compared to the typical MPP. The peak value and the frequency are not sensitive to different types of non-cylindrical embedded necks, and there is about 20 % improvement in the bandwidth with a trade-off of approximately 100 Hz shift in peak frequency towards the higher frequency side. Structured cores enhanced peak frequency (up to 25 %) and bandwidth (up to 10 %). Combined configurations exhibited limited synergistic enhancement, likely due to resonator interference effects. This study introduces a novel geometric strategy for tuning acoustic performance via coordinated neck and core design variations, enabling compact, lightweight, and tunable acoustic liners for low-frequency absorption. © 2025 Elsevier Ltd