NARESH AKKU

To be a part of progressive organization where I can use my Social skills and Technical skills towards the growth of the organization well as to enhance My knowledge.

Developed technical and analytical skills in fast-paced engineering environment. Adaptable and quick to learn, with focus on problem-solving and project management. Seeking to leverage these transferrable skills in new field to drive innovation and efficiency.

• Introduction to mechanical engineering design and manufacturing with fusion 360
• Mechanics of materials IV: Deflection, Blucking, combine loading & failure theories
• Advance manufacturing process Analysis
• Introduction to engineering mechanics

• Participated in Poster and Paper Presentation at CMRIT.
• Participated in Artificial intelligence and Machine Learning workshop at CMRIT.
• Participated summer training at CMRIT in the area of soft skills, problem solving.

IWU ID: 2856836

• Father's Name: A Laxman
• Mother's Name: A Swapna
• Date of Birth: 09/21/01
• Nationality: Indian

THERMAL ANALYSIS OF FRICTION STIR WELDING PROCESS PARAMETERS ON DISSIMILAR WELD JOINTS [ AISI 316, MONEL 400],

 Friction stir welding (FSW) as an efficient solid state joining process has numerous applications in industries. Temperature distribution analysis through simulation not only brings the possibility to characterize the microstructure of different zones, but also enables one to save cost and energy as optimum welding variables are obtained with less concern. In the present study, the temperature distribution during the friction stir welding (FSW) process of AISI 316 and Monel 400 was evaluated using finite element method (FEM). Since experimental measurements cannot be readily made in the weld region, it is difficult to understand physics in the stir zone of the welds without simulation. Abaqus software was applied to model the parts and simulate the process of welding, evaluate the effect of strain rate and generated heat. FE-results were verified by experimental results.

Outcomes: The comparisons revealed a good compatibility between the results. The effect of probe shape on temperature distribution was also studied. It was found that spherical pins result in the highest temperatures at workpieces with respect to cylindrical and tapered pins. Additionally, it was concluded that more heat is generated in workpieces as pin angle increases.

Team size:5

current status: Complete

Duration: 4 months.