A heat exchanger is a device used to transfer heat without mass transfer. The equipment must be designed according to established standards. The standard that is widely used is the standard
issued by TEMA (Tubular Exchanger Manufacturer Association). The results of the design of the
heat exchanger with these standards are considered less efficient in terms of the material. The
efficiency of the material used can be analyzed by stress analysis on the components that withstand the force, and one of these components is the tube sheet. Stress analysis on tube sheets can use finite element-based software. The results of the research show that the tube sheet design that refers to the TEMA standard is relatively safe because the maximum von Mises stress is below the yield strength of the material used, while the overdesign value is rather significant because the average von Mises stress is also far below the yield strength of the material used.

Sekulic DP. A reconsideration of the definition of a heat exchanger. Int J Heat Mass Transf. 1990;33(12):2748–50.

Bagi JS, Mane VN, Datye AB. Improvement in Quality Dimensions of Shell and Tube Type Heat Exchanger by Using Design. 2014;(September).

Thirumarimurugan M, Kannadasan T, Ramasamy E. Performance analysis of shell and tube heat exchanger using miscible system. Am J Appl Sci. 2008;5(5):548–52.

Costa ALH, Queiroz EM. Design optimization of shell-and-tube heat exchangers. Appl Therm Eng. 2008;28(14–15):1798–805.

Fesanghary M, Damangir E, Soleimani I. Design optimization of shell and tube heat exchangers using global sensitivity analysis and harmony search algorithm. Appl Therm. Eng. 2009;29(5–6):1026–31. Available from: http://dx.doi.org/10.1016/j.applthermaleng.2008.05.018

Hadidi A, Hadidi M, Nazari A. A new design approach for shell-and-tube heat exchangers using imperialist competitive algorithm (ICA) from economic point of view. Energy Convers Manag. 2013;67:66–74. Available from: http://dx.doi.org/10.1016/j.enconman.2012.11.017

Shirode KD, Rane DS, Naik MY. Comparison of Design and Analysis of Tubesheet Thickness by Using UHX Code of ASME and TEMA Standard. 2013;96–108.

Ozden E, Tari I. Shell side CFD analysis of a small shell-and-tube heat exchanger. Energy Convers Manag. 2010;51(5):1004–14.

Mizutani FT, Pessoa FLP, Queiroz EM, Hauan S, Grossmann IE. Mathematical programming model for heat-exchanger network synthesis including detailed heat-exchanger designs. 2. Network synthesis. Ind Eng Chem Res. 2003;42(17):4019–27.

Xu S, Wang W. Numerical investigation on weld residual stresses in tube to tube sheet joint of a heat exchanger. Int J Press Vessel Pip. 2013;101:37–44. Available from: http://dx.doi.org/10.1016/j.ijpvp.2012.10.004

Liang Q. Performance-Based Optimization of Structures: Theory and Applications . Engineering Optimization. London: Spon Press; 2007. Available from: http://doi.wiley.com/10.1002/0470867353%5Cnhttp://www.tandfonline.com/doi/abs/10.1080/03052150008941321

James R. Farr MHJ. Guidebook for the Design of ASME Section VIII Pressure Vessel. Angewandte Chemie International Edition, 6(11), 951–952. New York: ASME Press; 2001.

Li F, Xing J, Liu Y. Thermal analysis and stress analysis of the heat-exchange pipe based on ANSYS. In: Proceedings - 4th International Conference on Information and Computing, ICIC 2011. Phuket, Thailand; 2011. p. 283–5.

Yang L, Weinberger C, Shah YT. Finite element analysis on horizontal vessels with saddle supports. Comput Struct. 1994;52(3):387–95.

Claud Way. Plasticity in Physics. New York: The English Press; 2016.

Oberkampf WL, Trucano TG, Hirsch C. Verification, validation, and predictive capability in computational engineering and physics. Appl Mech Rev. 2004;57(5):345–84.

Franck H, Franck D. Forensic engineering fundamentals. Forensic Engineering Fundamentals. 2012. 1–454 p.

Khurmi, R., Gupta J. A Textbook of Machine design. Vol. I, System. Eurasia Publishing House (PVT.) LTD.; 2005.

Beyers WA, Zapke A, Venter G. Improved Cover Type Header Box Design Procedure. R&D J. 2015;31(December):76–85.