Polymer composites reinforced with natural fibers have been increasingly investigated and applied as engineering materials owing to their economical, technical, societal and environmental advantages. The malva fiber, particularly an important resource in the Amazon region in Brazil, only recently begin to be investigated as possible composite reinforcement for engineering application. However, the mechanical properties of composites reinforced with malva fiber are still unknown. In this paper, the flexural behavior of epoxy matrix composites reinforced with continuous malva fiber was for the first time investigated. Specimens of continuous malva fibers aligned along an epoxy matrix were press-molded. Three-points bending test were performed and the fractured specimens were analyzed by SEM. The results showed a marked improvement in the composites flexural properties with the increase in the amount of reinforced malva fiber. This improvement was found to match the Rule of Mixtures, which revealed the unique potential of malva composites for engineering applications.
The modern composite materials, especially those reinforced with synthetic fibers such as glass and carbon, have been used since last century to attend the demands required by most technological fields, from home appliances to aerospace. Natural fibers composites with biodegradable polymer matrices are considered environmentally friendly materials and currently accepted as possible substitutes for synthetic composites. These green composites can be safely discarded or composted at the end of their life without harm to the environment. Another alternative for synthetic composites is to apply natural lignocellulosic fibers as reinforcement of conventional polymer matrices and already used in the automobile industry. In addition to the environmental and societal advantages of the green composites, the lignocellulosic fiber reinforced conventional polymer composite also has economical and technical advantages. In the case of a fiber collected as a waste, the price of the composite can be considerably lower than "fiberglass". Furthermore, with high strength lignocellulosic fibers such as sisal, ramie and malva the specific strength of a composite may approach that of "fiberglass". Therefore the objective of the present work is to investigate the mechanical behavior of polymer matrix composites reinforced with high volumes of natural malva fibers subjected to tensile stresses.
ResumoAs fibras lignocelulósicas naturais são cada vez mais utilizadas como reforço em compósitos de matriz polimérica devido a vantagens econômicas e ambientais como serem renováveis e biodegradáveis. Este trabalho tem como objetivo estudar a influência de 10, 20 e 30% em volume de tecido de malva na resistência à tração de compósitos preparados submetidos à 5 toneladas de pressão. O tecido natural foi previamente lavado e seco à temperatura ambiente, depois disposto em uma matriz metálica com formato ósseo, em seguida, uma resina de poliéster (misturada com catalisadores) é vertida sobre o tecido dentro da matriz, o conjunto é transportado a uma prensa e submetido a 5 toneladas de carga. Observou-se que a resistência à tração cresceu significativamente com o aumento da quantidade de tecido natural de malva incorporado na matriz de poliéster. Esta melhora no desempenho pode ser diretamente associado à dificuldade de romper o tecido malva e ao tipo de trincas resultantes da interação do tecido de malva com a matriz. Palavras-chave: Resistência à tração; tecido natural; fibra de malva; resina de poliéster; compósitos.
TENSILE STRENGTH EVALUATION IN COMPOSITES WITH POLYESTER MATRIX INCORPORATING WITH NATURAL FABRIC OF MALVA FIBER AbstractNatural lignocellulosic fibers are increasingly being used as reinforcement in polymer matrix composites due to economic and environmental advantages as renewable and biodegradable materials. This work aims to study the influence of 10, 20 and 30% by volume of fabric with 100% malva fiber on tensile strength of samples prepared under 5 tons of pressure. Natural fabric were previously washed and dried at room temperature, then poured together with the polyester resin and catalyst mixture in the metal die in bone shape, and pressed to ensure the quality specimens. It was observed that the tensile strength was significantly increased with increased amounts of malva natural fabric embedded in polyester matrix. This improved performance can be directly associated with the difficulty of break imposed by the mauve fabric and the type of cracks resulting from the interaction of tissue mauve / matrix.
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