Abstract
This study investigates the morphological and physical/end-use properties of corn cob powder-filled recycled polypropylene composites. The composites were prepared by incorporating corn cob powder of particle sizes 150 µm, 300 µm and 425 µm respectively at filler loadings of 5 to 25 wt%. The properties were determined according to standard test procedures. Results showed that the incorporation of corn cob powder as filler resulted to enhancement of water absorption and solvent sorption, which were found to increase with both increase in filler loading and increase in filler particle size, probably due to the hydrophilic nature of corn cob powder. It was also discovered that solvent sorption was most pronounced with benzene, followed by toluene and lastly xylene, in accordance with the relative proximity of their solubility parameters to that of polypropylene. Flame propagation rate was also found to improve by the incorporation of corn cob powder due to its high content of cellulose, a combustible organic matter. However, specific gravities of the composites were found to be lower than for the unfilled polypropylene, an implication that the composites produced are lighter in weight than the unfilled. Specific gravity increased with increase in filler loading but decreased with increase in particle size. The Morphological studies showed increase in the number of spherulites with increase in filler loading and increase in the size of the spherulites with increase in particle size. Further observation showed that the particle sizes and pores sizes detected increased with increase in filler particle size probably due to poor interaction and distribution of coarse particles. It is hoped that this present study will to help place the usefulness of corn cob as filler in the development of thermoplastic composites in future and develop its niche in the scientific record.
Highlights
There is a growing interest in the use of natural/bio-fibers/fillers as reinforcements for biodegradable polymers because natural/bio-fibers/fillers have the functional capability to substitute for glass fibers
ignition time (It) can be generally observed that all the physical and end-use properties investigated increased with increase in filler loading, except flame propagation rate which decreased with increase in filler loading
The general trend observed is that all the end-use properties of the filled polypropylene composites are higher than those of the unfilled polypropylene
Summary
There is a growing interest in the use of natural/bio-fibers/fillers as reinforcements for biodegradable polymers because natural/bio-fibers/fillers have the functional capability to substitute for glass fibers. Rising oil prices and increased activity in regards to environmental pollution prevention have pushed recent research and development of biodegradable polymers. The use of agricultural resources as source of raw materials to the industry provides a renewable source, but could generate a non-food source of economic development for farming and rural areas. Appropriate research and development in the area of agricultural based fillers/fibers filled plastics could lead to new value-added, non-food uses of agricultural materials. The cost of natural fibers are in general less than the plastic, and high fiber loading can result in significant material cost savings. The cost of compounding is unlikely to be much more than for conventional mineral/inorganic based presently used by plastics industry. Significant environmental advantages include: preservation of SciPress applies the CC-BY 4.0 license to works we publish: https://creativecommons.org/licenses/by/4.0/
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