Your search keyword '"Surbhi Kore"' showing total 5 results

1. Effect of the Segmental Structure of Thermoplastic Polyurethane (Hardness) on the Interfacial Adhesion of Textile-Grade Carbon Fiber Composites

Author

Surbhi Kore, Merlin Theodore, and Uday Vaidya

Subjects

Polymer morphology, Thermoplastic polyurethane, Textile, Materials science, Carbon fiber composite, Polymers and Plastics, business.industry, Process Chemistry and Technology, Organic Chemistry, Polymer composites, Interfacial adhesion, Composite material, business

Abstract

In polymer composites, the fiber–matrix interface is primarily influenced by the surface treatment of the fibers and polymer morphology. Previous studies have investigated the effect of surface tre...

Published

2021

2. Textile-Grade Carbon Fiber-Reinforced Polycarbonate Composites: Effect of Epoxy Sizing

Author

Nitilaksha Hiremath, Uday Vaidya, Dayakar Penumadu, Stephen Young, Surbhi Kore, Vidyarani Sangnal Matt Durandhara Murthy, and Merlin Theodore

Subjects

Textile, Materials science, business.industry, General Chemical Engineering, Polyacrylonitrile, Compression molding, 02 engineering and technology, General Chemistry, Epoxy, 021001 nanoscience & nanotechnology, Industrial and Manufacturing Engineering, Sizing, chemistry.chemical_compound, Matrix (mathematics), 020401 chemical engineering, chemistry, visual_art, visual_art.visual_art_medium, 0204 chemical engineering, Polycarbonate, Composite material, 0210 nano-technology, business

Abstract

Epoxy-sized textile-grade polyacrylonitrile (PAN) carbon fiber (TCF) with 450 K filaments (CFTF, ORNL) was reinforced in the polycarbonate (PC) matrix using a compression molding technique. The epo...

Published

2021

3. Characterization of textile-grade carbon fiber polypropylene composites

Author

Merlin Theodore, Surbhi Kore, Pritesh Yeole, Nitilaksha Hiremath, Shailesh Alwekar, Uday Vaidya, and N. Krishnan P. Veluswamy

Subjects

Textile, Materials science, Polymers and Plastics, business.industry, Polypropylene composites, Materials Chemistry, Ceramics and Composites, Composite material, Thermal analysis, business, Characterization (materials science)

Abstract

In this work, we consider low-cost carbon fiber produced with a textile-grade precursor. The objective of the study is to investigate textile-grade carbon-fiber-reinforced-polypropylene composites (TCF-PP) from compounded pellets for mechanical and thermal characterization. Four sets of pellets with 1%, 5%, 10%, and 15% reinforcement were manufactured using textile-grade carbon fiber (TCF) and polypropylene (PP) by twin-screw compounding. The addition of TCFs through gravimetric feeder directly in the extruder resulted in lower fiber content; however, side feeder has shown good potential. The pellets were further processed in extrusion compression molding to manufacture plaques. An increase in fiber loading has a negligible effect on fiber attrition as fiber length distribution variation between 1% and 15% reinforced pellets was very small. The addition of TCFs in PP showed a significant improvement in mechanical properties. The tensile strength and modulus of the composite were 26% and 161%, respectively, improved by the addition of 10 wt% TCF. Similar results were observed in the flexure test. However, the impact properties were reduced by 25.54% by the addition of 15% TCF.

Published

2020

4. Performance of hybridized bamboo-carbon fiber reinforced polypropylene composites processed using wet laid technique

Author

Lee Slaven, Surbhi Kore, Hicham Ghossein, John Unser, David Knight, Ryan Spencer, and Uday Vaidya

Subjects

Polypropylene, Bamboo, Materials science, Flexural modulus, Mechanical Engineering, Composite number, Surface treatment, Izod impact strength test, Mechanical properties, Vibrational damping, chemistry.chemical_compound, chemistry, Flexural strength, Mechanics of Materials, Ceramics and Composites, Bamboo fiber, TA401-492, Fiber, Carbon fiber, Composite material, Hybrid material, Materials of engineering and construction. Mechanics of materials

Abstract

The end-of-life vehicles (ELV) regulations motivate hybrid materials usage in automotive industries to optimize properties at reduced cost and increase eco-friendly designs. This research explores hybrid compositions of natural bamboo fiber and synthetic carbon fiber. The goal of hybridization was to synergistically benefit from each constituent– i.e., sustainability, energy absorption and superior damping from bamboo, and high strength and stiffness from carbon fiber. Carbon fibers (CF), bamboo fibers (BF) and polypropylene (PP) fibers were dispersed in water to produce wet-laid hybrid mats. The mats were compression molded into consolidated panels to obtain the hybrid composite(s) (BF-CF-PP). Four formulations with different fiber-resin weight percent were designed and produced including- BF-PP (30/70), BF-PP (50/50), BF-CF-PP (32/8/60), and BF-CF-PP (8/32/60). The effect of (a) fiber length, (b) surface treatment, (c) fiber content, and (d) consolidation pressure on the mechanical properties were examined. The improved mechanical (flexural strength 76.4 MPa, flexural modulus 4.1 GPa, ILSS 12.4 MPa and impact strength 49.9 KJ/m2) and vibrational damping (1.05%) properties showed that the BF-CF-PP (8/32/60) provided higher properties compared to the other variants. The projected properties at various stoichiometric ratios of carbon and bamboo fiber revealed that the properties of hybrid composites could be tailored to produce desirable, cost-effective, and sustainable automotive components.

Published

2021

5. Finite Element Modeling of the Fiber-Matrix Interface in Polymer Composites

Author

Vinoy Thomas, Merlin Theodore, Surbhi Kore, Uday Vaidya, Daljeet K. Singh, and Amol Vaidya

Subjects

fiber matrix interface, finite element analysis, Materials science, 02 engineering and technology, lcsh:Technology, Specific strength, Stress (mechanics), Matrix (mathematics), 0502 economics and business, Shear stress, medicine, Fiber, Composite material, lcsh:Science, Engineering (miscellaneous), Specific modulus, lcsh:T, 05 social sciences, Stiffness, 021001 nanoscience & nanotechnology, Finite element method, Ceramics and Composites, lcsh:Q, medicine.symptom, 0210 nano-technology, 050203 business & management

Abstract

Polymer composites are used in numerous industries due to their high specific strength and high specific stiffness. Composites have markedly different properties than both the reinforcement and the matrix. Of the several factors that govern the final properties of the composite, the interface is an important factor that influences the stress transfer between the fiber and matrix. The present study is an effort to characterize and model the fiber-matrix interface in polymer matrix composites. Finite element models were developed to study the interfacial behavior during pull-out of a single fiber in continuous fiber-reinforced polymer composites. A three-dimensional (3D) unit-cell cohesive damage model (CDM) for the fiber/matrix interface debonding was employed to investigate the effect of interface/sizing coverage on the fiber. Furthermore, a two-dimensional (2D) axisymmetric model was used to (a) analyze the sensitivity of interface stiffness, interface strength, friction coefficient, and fiber length via a parametric study; and (b) study the shear stress distribution across the fiber-interface-matrix zone. It was determined that the force required to debond a single fiber from the matrix is three times higher if there is adequate distribution of the sizing on the fiber. The parametric study indicated that cohesive strength was the most influential factor in debonding. Moreover, the stress distribution model showed the debonding mechanism of the interface. It was observed that the interface debonded first from the matrix and remained in contact with the fiber even when the fiber was completely pulled out.

Published

2020