Bibin Joy

A dedicated and dynamic postgraduate mechanical engineer with a master's degree in Mechanical Engineering, showcasing expertise in design engineering, process management, planning, scheduling, QA/QC, project management, and risk management. A strong technological background has led to the successful management of engineering projects and valuable guidance in research, design, and production processes, resulting in innovative mechanical components. With a self-driven and adaptable nature, excel in fostering collaboration, building stakeholder relationships, and driving organizational development for improved project performance. A passion for excellence and continuous pursuit of innovative solutions make a highly valuable asset in any team or organization I join.

Design and Optimization of 3D Printed Pen and Holder for Deakin University

• Conducted extensive market research, which involved analyzing existing products, identifying potential gaps in the market, and pinpointing key opportunities for product innovation.

• Utilized Autodesk Fusion 360, a computer-aided design (CAD) software, to meticulously craft detailed 3D models of the pen and holder, incorporating cutting-edge design features and functional elements.

• Employed rapid prototyping techniques to create physical prototypes of the pen and holder, facilitating hands-on evaluation of the design's ergonomics, usability, and overall user experience.

• Performed Finite Element Analysis (FEA) simulations to analyze stress distribution and structural integrity, ensuring the product's resilience and longevity under various real-world operating conditions.

• Demonstrated a keen eye for detail by conducting thorough product validation tests and simulations to certify the pen and holder's performance and safety.

Developing Methodology for Post Processing of 3D digitized Heritage by Reverse Engineering for Deakin University

• Conducted extensive and interdisciplinary research on data capturing technologies, including 3D scanning, photogrammetry, and laser scanning, to develop a robust and accurate process for digitizing heritage objects.

• Analyzed various data capture methods and equipment to identify the most suitable technology for capturing intricate details and complex geometries of historical artifacts and structures.

• Utilized industry-leading software tools such as SolidWorks, Autodesk Inventor, Fusion 360, Autodesk Recap, and Geomagic Studio to process and manipulate the 3D data obtained from the digitization process..

• Implemented advanced data processing techniques to address challenges such as noise reduction, hole filling, and surface smoothing, achieving a level of accuracy that faithfully represented the original heritage objects

• A specialized post-processing method was developed for 3D digitized heritage objects. This method not only preserved their historical authenticity but also made it easier to include them in heritage databases and virtual exhibitions.