Abstract
Polymeric syntactic foams are composites made from the mixture of Hollow Glass Microspheres (HGM) and polymer matrices. One of their main characteristics is their low density and the production of these composites using a matrix derived from renewable sources potentiates their development without neglecting sustainability. In this paper , the properties of High Density Polyethylene (HDPE)/HGM syntactic foams containing 1% and 5% w/w HGM and 5% w/w of a compatibilizer are assessed. The composites were prepared by two processing routes: single screw extruder and twin screw extruder. The morphology and mechanical properties (tensile and impact) of the syntactic foams thus manufactured were ascertained. Morphological analysis indicated that matrix/filler adhesion was poor for all samples and that the best HGM dispersions were obtained in twin screw extruded samples. Mechanical properties were affected by the processing route adopted and by the content of hollow glass microspheres added. Elastic modulus, tensile strength and strain were reduced by 20, 10 and 23%, respectively, in systems processed in a twin screw extruder. Impact strength was the exception, with an increase of more than 300%. Higher contents of hollow glass microspheres led to reductions in mechanical strength of the syntactic foams, varying from 5% for the elastic modulus to 50% for strain.
Highlights
The search for lighter materials to facilitate transport and use, has led to a growing number of studies in areas, such as science, engineering and design
The aim was to observe the interactions of the syntactic foams constituents and to visualize the damage caused to the filler at the end of each processing and to correlate it with the properties of the systems
The high integrity of the glass microspheres after processing is in agreement to what was observed by BARBOZA and DE PAOLI (2002)[26] for PP/Hollow Glass Microspheres (HGM) and by Kumar et al (2016)[27] for High Density Polyethylene (HDPE)/HGM syntactic foams
Summary
The search for lighter materials to facilitate transport and use, has led to a growing number of studies in areas, such as science, engineering and design. Polymers and polymer composites are promising options to replace metallic and ceramic materials[1] in several applications as they are light in weight, have a good set of mechanical properties, are easy to process, can be molded in different shapes and can be colored. Composites are created in order to obtain new materials with unique properties. If the matrix is a polymer, a polymer composite is obtained. The development of composites is currently one of the fastest, simplest and cheapest techniques to combine material properties leading to products with distinct characteristics which are not typical of the matrix. The scientific community has expanded research so that composites can be obtained with materials that, in addition to their economic advantages, are more ecologically sound, either within the production chain, applications or disposal after use[2]
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