Influence of Pressure Drop, Reynolds Number and Temperature in the Design of Double Pipe Heat Exchanger on Hot Fluid Side in Inner Pipe
International Journal of Mechanical Engineering |
© 2017 by SSRG - IJME Journal |
Volume 4 Issue 12 |
Year of Publication : 2017 |
Authors : V Lokesh Varma, Suresh Babu Koppula, Dr N.V.V.S.Sudheer |
How to Cite?
V Lokesh Varma, Suresh Babu Koppula, Dr N.V.V.S.Sudheer, "Influence of Pressure Drop, Reynolds Number and Temperature in the Design of Double Pipe Heat Exchanger on Hot Fluid Side in Inner Pipe," SSRG International Journal of Mechanical Engineering, vol. 4, no. 12, pp. 28-36, 2017. Crossref, https://doi.org/10.14445/23488360/IJME-V4I12P105
Abstract:
A feature of heat exchanger design is the process of specifying a design, Heat transfer area, pressure drop, Reynolds number and Temperature are checking whether the assumed design satisfies all requirement or not. The idea of this paper is how to design the double pipe heat exchanger which is the majority type of liquid –to- liquid heat exchanger. General design consideration and design processes are also illustrated in this paper. Also the main components of heat exchanger are shown in drawing and its detail discussion is given. Heat exchanger is a heat transfer device that is used for transfer of internal thermal energy between two or more fluids available at different temperatures. Heat exchanger is one of the important devices in cooling and heating process in the process, power, petroleum, transportation, air-conditioning, refrigeration, cryogenic, heat recovery, building, and others.
Keywords:
Coefficient of heat transfer, Double pipe Heat Exchanger, length and diameter, overall heat transfer coefficient.
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