Your search keyword '"Subramanya, Raghavendra"' showing total 3 results

1. Enhancement of tensile strength and fracture toughness characteristics of banana fibre reinforced epoxy composites with nano MgO fillers

Author

Subramanya Raghavendra, Raveendra Rajanabilaguli Sannegowda, Arun Kumar Rudrappa, and Satish Kumar Kibbanahalli Basavarajaiah

Subjects

Nano Magnesium oxide, Fracture toughness, Banana fiber, Alkali treated, Technology

Abstract

Natural fibre reinforced polymer composites have drawn the attention of researchers in the creation of novel materials suitable for industrial applications. These polymer composites have favourable mechanical characteristics. Epoxy polymer's versatility and diversity make it suitable for a wide range of industrial applications. The mould casting technique approach was utilised in this work to develop polymer composites using alkali-treated banana fibres and filled with MgO nanoparticle. The study was conducted on the characteristics of Nano MgO, as well as its mechanical qualities such as fracture toughness and surface morphology. The incorporation of Nano MgO enhanced the fracture toughness of the polymer composites with the addition of 1 % MgO. The scanning electron microscopy analysis of the surface morphology revealed the presence of brittle fracture in the specimen.

Published

2024

2. Surface Modification of Banana Fiber and its Influence on Performance of Biodegradable Banana-Cassava Starch Composites

Author

Subramanya Raghavendra and S.S. Prabhakara

Subjects

0106 biological sciences, Materials science, Starch, food and beverages, General Medicine, 010501 environmental sciences, 01 natural sciences, chemistry.chemical_compound, chemistry, 010608 biotechnology, Surface modification, Banana fiber, Composite material, 0105 earth and related environmental sciences

Abstract

Natural fibers, in particularly lignocellulosic fibers are attracting material scientists now days, due to their comparative advantages over synthetic fibers. Biodegradable composites reinforced with short banana fibre after alkali treatment along with cassava starch matrix were prepared using the hot compression method. The mechanical properties like tensile strength and impact strength were investigated. Mechanical properties of the composites made from alkali treated fibres were superior to the untreated fibres. SEM observations on the fracture surface of composites showed that the surface modification of the fibre occurred and improved fibre–matrix adhesion. Keywords: Surface modification; banana fiber; Biodegradable composites; Mechanical properties; Matrix.

Published

2019

3. Evaluation of Structural, Tensile and Thermal Properties of Banana Fibers.

Author

Subramanya, Raghavendra, Satyanarayana, Kestur Gundappa, and Shetty Pilar, Balachandra

Subjects

*PLANT fibers, *TENSILE strength, *STRENGTH of materials

Abstract

Recognizing the importance of properties of the plant fibers for their use in polymeric composites and nonavailability of data on tensile, thermal, and other properties of banana fibers of Karnataka (India), a study was undertaken with the objective of determining some of these properties. This article presents determination of structural aspects of the fibers by Fourier transform infrared (FTIR) spectroscopy and X-ray diffraction (XRD) techniques; obtaining stress-strain curves and tensile properties by tensile testing; finally, thermal properties by differential scanning calorimetry and thermogravimetric analysis. FTIR spectrum of banana fibers showed aromatic character, while XRD results indicated the fiber to have mainly the cellulose I structure and crystallinity index of 52%. Thermal-degradation details of fiber samples were revealed by thermal studies. Stress-strain curves of banana fibers suggested their brittle nature with moderate values of tensile strength, but low percentage elongation. Weibull analysis of obtained tensile strength values revealed variation of “characteristic strength” values from 3800 MPa at 99% reliability to 22,700 MPa with 0.01% reliability. Morphology studies revealed the number of defects along the length of the fiber, while fractured surface exhibited flat surface with intracellular fractures clearly indicating brittle nature of the fiber. [ABSTRACT FROM PUBLISHER]

Published

2017