Resumen:: Effect of Fiber Angle on Mechanical Properties of the Natural Fiber-Reinforced Polymer Through Numerical Analysis :: SILO. Sistema nacional de repositorios digitales. Uruguay

Artículo Publicado

Effect of Fiber Angle on Mechanical Properties of the Natural Fiber-Reinforced Polymer Through Numerical Analysis

Efecto del ángulo de fibra sobre las propiedades mecánicas del polímero reforzado de fibra natural a través del análisis numérico

Efeito do ângulo de fibra nas propriedades mecânicas do polímero reforçado com fibra natural por meio de análise numérica

Anas Nisar, Syed - Jamil, Tariq

Detalles Bibliográficos
Fecha de publicación:	2023
Temas:	Fibra natural Materiales compuestos Análisis numérico Análisis de estructura Respuesta vibratoria Natural Fiber Composite Materials Numerical Analysis Structure Analysis Vibrational response Fibra natural Materiais compostos Análise numérica Análise de estrutura Resposta vibracional
Idioma	Español
Institución:	Universidad de Montevideo
Repositorio:	REDUM
Enlace(s):	http://revistas.um.edu.uy/index.php/ingenieria/article/view/1192
Nivel de acceso:	Acceso abierto
Licencia:	Atribución 4.0 Internacional

Resumen:
Sumario:	This study focuses on the mechanical behavior of natural fiber-reinforced polymer composites (NFRPs), which are gaining prominence as sustainable materials due to their biodegradability and eco-friendliness. In this study, we aimed to gain a profound understanding of the mechanical behavior of selected NFRPs. Static structural analysis was conducted to simulate tensile effects, while vibrational analysis was performed to predict natural frequencies. The results indicated that all fibers exhibited minimum stress at the 67.5° angle and maximum stress at the 22.5° angle during tensile testing. Additionally, minimum deformation occurred at the 0° angle, whereas maximum deformation was observed at the 67.5° angle. Interestingly, the NFRPs exhibited similar natural frequencies for the lower modes (1st and 2nd), with negligible alterations due to fiber angles. The core aim of this study is to showcase the practicality and viability of the investigated NFRPs by employing sophisticated finite element analysis to anticipate their material behavior beforehand, allowing for a comprehensive comparison of the natural frequencies, stresses, and deformations with traditional Carbon Fiber Reinforced Polymer (CFRP) composites, thereby exploring the potential of NFRPs as feasible alternatives.