Calotropis Gigantea Fiber-epoxy Composites: Influence of Fiber Orientation on Mechanical Properties and Thermal Behavior

Global warming and environmental pollution issues are the challenges that have prompted researchers around the world to recognize biodegradable material as an alternate solution for fossil fuel dependency. The previous literature motivates the researchers to identify alternatives to artificial reinforcement in composite materials. This work utilizes Calotropis gigantea fiber as a strengthening agent, which is generously available as an unused plant in India. Compression molding technique was used for the preparation of specimens with different fiber orientation (0 degrees, 15 degrees, 30 degrees, 45 degrees, 60 degrees, 75 degrees, 90 degrees, 0 degrees/90 degrees, and 0 degrees/45 degrees/90 degrees) Specimen with 0 degrees fiber orientation registered a maximum value of 142.46 MPa, 93.13MPa, and 81.21 kJ/m(2) in Flexural test, Tensile test and Impact test, respectively, than the other orientations. Mechanical testing results establish that the orientation of the fiber will prominently influence in improving the strength. The thermal studies on Calotropis gigantea fiber-epoxy composites through Thermogravimetric Analysis and Differential Scanning Calorimetry reveal that the composite will withstand more than 600 degrees C temperature and confirm its thermal stability. The combined findings show that Calotropis gigantea fiber in polymer composite can be a possible reinforcing material and suitable for manufacturing accessories for automobile and household applications.

Automated summary

Global warming and environmental pollution have led researchers to explore biodegradable materials as alternatives to fossil fuels. This study utilizes Calotropis gigantea fiber as a strengthening agent and demonstrates the significant impact of fiber orientation on material strength. Thermal analysis confirms the composite's thermal stability. These findings suggest that Calotropis gigantea fiber can be used as a reinforcing material for manufacturing automotive and household products.