{"references": ["Kanti, P. K., Karthika, U. P., Ali, S., Kumar, N. S., & Chandran, C. S. (2016). CFD Analysis of Shell and Tube Heat Exchanger. International Journal of Engineering Research, 5(SP 6), 1249-1252.", "Niphade, A., Chavan, H.(2016). Design, CFD Analysis of Shell & Tube Heat Exchanger CFD Analysis for Dairy Application. International Journal of Advance Foundation And Research In Science & Engineering (IJAFRSE)2(9).", "Uppal, A., Kumar, V, Singh, C.(2014). Analysis of Heat Transfer Enhancement in a Heat Exchanger Using Various Baffle Arrangements. IJRMET 4(2).", "Ali, S. M. Z. M. S., Krishna, K. M., Reddy, S. D. V. V. S., & Ali, S. R. S. M. (2015). Thermal analysis of double pipe heat exchanger by changing the materials using CFD. International Journal of Engineering Trends and Technology, 26(2), 95-102.", "Kumar, K, Srikesh, M.(2015). Computational Fluid Dynamics of Parallel Flow Heat Exchanger. International Journal of Sciences: Basic and Applied Research (IJSBAR) 24(5):111-120.", "Johnson, J., Abdul Anzar, V. M., Shani, A., Harif Rahiman, P., Hashmi Hameed, T. S., & Nithin, V. S. (2015). CFD analysis of double pipe Heat Exchanger. International Journal of Science, Engineering and Technology Research (IJSETR), 4(5), 1283-1286.", "Sarma, S., & Das, D. H. (2012). CFD Analysis of Shell and Tube Heat Exchanger using triangular fins for waste heat recovery processes. IRACST\u2013Engineering Science and Technology: An International Journal (ESTIJ), ISSN, 2250-3498."]}

As a part of this project, CFD analysis is performed on pipe with fins for various header sections. Heat exchangers are used in a number of sectors, and one such heat exchanger (a pipe with fins) is considered in this paper. It is created to meet the industry's business requirements. The condenser is designed using the CREO parameters programme. The design procedure resulted in a condenser with 22 tubes, 20mm outer diameter, 18mm inner diameter, and a length of 90mm.Because the design technique does not specify the type of to be utilized header, investigated 3 different headers that provide equal velocity in the tube's entrance. Various geometries were used in multiple points of header's input nozzle Optimal location of the, which might be used for equal liquid and velocity distribution across each and every tube, is done using CFD models. The major goal of this project is to employ commercial Computational Fluid Dynamics [CFD] software to verify the planned condenser. CREO parameters 3.0 software is used to create a symmetric representation of the simplified geometry of a condenser [Pipe with Fins] for simulation purposes. The velocity, pressure, and temperature characteristics are calculated using the fin as a rectangular plate and air and water as fluids. The procedure is then repeated for the plate with a hole.