This repository contains an overview of some of the notable mechanical engineering projects I completed during my undergraduate journey.
Apart from an opportunity to work with the Surface Science and Tribology (SST) Lab for my capstone project as part of my Mechanical Engineering degree, I took up an additional initiative under the Opportunities for Undergraduate Research (OUR) scheme to pursue research into the hydrophobic properties of marine grade alloys for their ‘self-cleaning’ applications, a novel method with applications across industries. This project secured substantial departmental funding and received recognition from across departments for its domain-agnostic applications. My thesis and capstone project was centered around honing my technical skills and delving into one of the foundational principles of the engineering domain. We used biomimicry and Computational Fluid Dynamics (CFD) to design and create nanostructures that would optimize the erosion-corrosion resistance of certain alloys. We devised a low-cost and time-efficient solution to create these structures on additively manufactured (3D printed) samples.
For any further queries, feel free to reach out through the communication channels provided.
- We implement biomimicry to create different types of microstructures on alloys to understand how it affects their erosion and corrosion properties. We used a low-cost and more efficient solution of Imprinting to create these structures and extended the study to compare the performance of these microstructures in Conventionally and Additively manufactured (3D Printed) samples for applications in various industries. (May 2022)
- We used Computational Fluid Dynamics (CFD: Ansys Fluent and Workbench 2022 R1, CAD: SpaceClaim 2022 R1) to simulate erosive wear on microtextured substrates to understand how we could further optimize the Depth, Cross-Sectional Shape, and Pattern types of the structures, to minimize the overall erosive wear under its respective operating conditions. (December 2021)
- We studied and modeled the various factors that govern the motion of a liquid droplet on the inclined surfaces of Marine Grade Aluminum (AA5083) and optimized its performance under various operating conditions, tuning its hydrophobic properties for self-cleaning applications across sectors. (June 2021)
All work has been done in collaboration with the Department of Mechanical Engineering, Shiv Nadar University. The content, materials, and any other elements associated with this project, including but not limited to text, graphics, images, code, and design, are the intellectual property of the author and are protected by copyright law. Any commercial use or distribution of the materials without prior written consent from the author is strictly prohibited. You may not modify or alter the materials, remove any copyright or proprietary notices, or use the materials in a way that suggests an association with the author without express permission.