International Journal of Science, Engineering and TechnologyAuthors: Sovaran Singh Yadav, Khemraj beragi
Abstract: Power generating, chemical processing, and oil refining are just a few of the many industries that rely on tube and shell heat exchangers because of their versatility, high-pressure handling capacity, and sturdy architecture. Limitations in thermal effectiveness and operational costs caused by problems including flow maldistribution, contamination, and high-pressure drop are common in traditional systems. Analytical and computational approaches to optimising the design and efficiency of shell and tube heat exchangers are investigated in this work. Emphasis is placed on key design considerations including baffle configuration, tube arrangement, material selection, and flow orientation. Analytical models using LMTD, NTU-effectiveness methods, and pressure drop equations are applied to evaluate thermal performance. Additionally, CFD simulations are used to validate and visualize improvements in flow and heat transfer behavior. Case studies highlight the advantages of baffle optimization and AI-assisted predictive diagnostics. The paper also discusses emerging innovations such as the use of nanofluids, additive manufacturing of complex geometries, and smart sensors for real-time monitoring. Challenges related to material constraints, maintenance access, and computational limitations are also addressed. The findings suggest that through integrated design and advanced analysis, tube and shell heat exchangers can be significantly enhanced for modern industrial applications.
DOI: http://doi.org/10.5281/zenodo.17104172
