Preparation and characterization of olive pit powder as a filler to PLA-matrix bio-composites

• Published in: Powder technology Vol. 255; no. SI; pp. 10 - 16
• Main Authors: Koutsomitopoulou, A.F., Bénézet, J.C., Bergeret, A., Papanicolaou, G.C.
• Format: Journal Article Conference Proceeding
• Language: English
• Published: Amsterdam Elsevier B.V 01.03.2014; Elsevier
• Subjects: Applied sciences; Chemical engineering; Engineering Sciences; Exact sciences and technology; Grinding; Materials; Mechanical properties; Miscellaneous; Morphology; Olive pit powder; PLA; Size distribution; Solid-solid systems; Mechanical properties; Olive pit powder; Size distribution; PLA; Grinding; Morphology; Planetary mill; Grinding(comminution); Density; Composite material; Powder; Additive; Particle size distribution; Loading; Preparation; Production; Manufacturing; Recycling; Filler; Strength; PIA
• ISSN: 0032-5910; 1873-328X
• DOI: 10.1016/j.powtec.2013.10.047

This study is focused on recycling potential of some waste materials, such as olive pits, i.e. the solid phase derived from an olive oil mill, blended with thermoplastic polymers and used for the production of new materials applied in manufacturing containers and formworks. The olive pit powders are described and characterized. Then the powder is introduced in a bio-based and biodegradable matrix (polylactic acid, PLA) at various percentages. In this study, a comparison of the size distribution and the densities of olive pit powders according to the grinding methods (planetary mill and centrifugal mill) was made. The analyses showed that olive pits can be further studied as additive for the production of green materials. The development of an agricultural based polymer matrix compatible with olive pits and consequently a fully biodegradable composite system is the future and ultimate goal of the research undertaken. For that purpose, composite samples made out of PLA matrix, reinforced with olive pit powders were manufactured and mechanically characterized. With filler loading, an increase in the tensile modulus but a decrease of the flexural strength may be due to the poor interfacial bonding between olive pit powder and PLA. SEM cross section analysis of fracture surface under flexion of PLA/olive pit powder biocomposites (magnitude ×500 — 15wt.% olive pit powder B). [Display omitted] •A novel biocomposite was manufactured and studied.•The grinding method applied affects the size distribution.•Thermal analysis shows no significant changes on the thermal degradation temperature.•With filler loading, an increase in the tensile modulus is observed.•A small decrease in tensile strength with filler volume fraction is observed.