Revista Chapingo Serie Ciencias Forestales y del Ambiente
Extrusion of foamed wood-plastic composites. Part I: Physical and morphological characterization
ISSNe: 2007-4018   |   ISSN: 2007-3828
Vol. 23 No. 3 (2017), Scientific articles
Vol. 23 No. 3 (2017)

Extrusion of foamed wood-plastic composites. Part I: Physical and morphological characterization

Scientific articles
Published 2023-12-19
Pablo A. Moreno
Universidad de Los Andes, Conjunto Forestal, Facultad de Ciencias Forestales y Ambientales. Av. Chorros de Milla, Campus Universitario Forestal. Mérida, Venezuela.
Aldo Ballerini
Universidad del Bío-Bío, Facultad de Ingeniería, Departamento de Ingeniería en Madera. Av. Casilla 5-C, Collao 1202. Región del Bío-Bío. Concepción, Chile.
William Gacitúa
Universidad del Bío-Bío, Facultad de Ingeniería, Departamento de Ingeniería en Madera. Av. Casilla 5-C, Collao 1202. Región del Bío-Bío. Concepción, Chile.
Denis Rodrigue
Université Laval, Faculté des Science et de Génie, Génie Chimique. Pavillon Adrien-Pouliot 1065, Avenue de la Médecine Local 3546. Québec, Canada.
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Keywords

High-density polyethylene
cellular morphology
Hydrocerol
maleated polyethylene

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A. Moreno, P. ., Ballerini, A. ., Gacitúa, W., & Rodrigue, D. . (2023). Extrusion of foamed wood-plastic composites. Part I: Physical and morphological characterization. Revista Chapingo Serie Ciencias Forestales Y Del Ambiente, 23(3), 385–400. Retrieved from https://revistas.chapingo.mx/forestales/article/view/761
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##article.highlights##

  • Density reduction in wood-plastic composites with Hydrocerol foaming at 1 and 3 % was less than 10 %.
  • Density reduction in thermoplastic polymer (virgin and recycled) with Hydrocerol was greater than 20 %.
  • Cell density was higher in foamed composites.
  • Wood content (30 %) decreased average cell size.

Abstract

Introduction: The use of wood-plastic composites (WPCs) has been limited due to their low impact strength and high density compared to natural wood.
Objective: To characterize the cellular morphology and density of WPCs prepared with virgin and recycled polyethylene, and Pinus radiata wood.
Materials and methods: The polymer and the foamed WPCs were manufactured by an extrusion process. The virgin and recycled high-density polyethylene was mixed separately with P. radiata wood. The plastic/wood ratios were 80/20 and 70/30, with an endothermic foaming agent (Hydrocerol 1700 at 1 and 3 %), a coupling agent (Licocene 4351), and a lubricating agent (Licolub H12) added.
Results and discussion: The density of virgin polymer, with 1 and 3 % foaming agent, was reduced by 39 and 20 %, respectively, but in the recycled polymer the reduction was 18 and 23 %, respectively. In the foamed WPCs, the reduction was less than 10 %. The foamed composites had smaller bubble diameter and higher cell density. The void fraction was higher in the virgin polymer at 3 % foaming.
Conclusion: The use of a foaming agent gave better physical properties to the composites.

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References

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