%0 Journal Article %1 ER:ER1272 %A Wildi-Tremblay, Philippe %A Gosselin, Louis %D 2007 %I John Wiley & Sons, Ltd. %J International Journal of Energy Research %K 2007 design economics heat-exchanger %N 9 %P 867--885 %R 10.1002/er.1272 %T Minimizing shell-and-tube heat exchanger cost with genetic algorithms and considering maintenance %U http://dx.doi.org/10.1002/er.1272 %V 31 %X This paper presents a procedure for minimizing the cost of a shell-and-tube heat exchanger based on genetic algorithms (GA). The global cost includes the operating cost (pumping power) and the initial cost expressed in terms of annuities. Eleven design variables associated with shell-and-tube heat exchanger geometries are considered: tube pitch, tube layout patterns, number of tube passes, baffle spacing at the centre, baffle spacing at the inlet and outlet, baffle cut, tube-to-baffle diametrical clearance, shell-to-baffle diametrical clearance, tube bundle outer diameter, shell diameter, and tube outer diameter. Evaluations of the heat exchangers performances are based on an adapted version of the Bell–Delaware method. Pressure drops constraints are included in the procedure. Reliability and maintenance due to fouling are taken into account by restraining the coefficient of increase of surface into a given interval. Two case studies are presented. Results show that the procedure can properly and rapidly identify the optimal design for a specified heat transfer process. Copyright © 2006 John Wiley & Sons, Ltd.

@article{ER:ER1272, abstract = {This paper presents a procedure for minimizing the cost of a shell-and-tube heat exchanger based on genetic algorithms (GA). The global cost includes the operating cost (pumping power) and the initial cost expressed in terms of annuities. Eleven design variables associated with shell-and-tube heat exchanger geometries are considered: tube pitch, tube layout patterns, number of tube passes, baffle spacing at the centre, baffle spacing at the inlet and outlet, baffle cut, tube-to-baffle diametrical clearance, shell-to-baffle diametrical clearance, tube bundle outer diameter, shell diameter, and tube outer diameter. Evaluations of the heat exchangers performances are based on an adapted version of the Bell–Delaware method. Pressure drops constraints are included in the procedure. Reliability and maintenance due to fouling are taken into account by restraining the coefficient of increase of surface into a given interval. Two case studies are presented. Results show that the procedure can properly and rapidly identify the optimal design for a specified heat transfer process. Copyright © 2006 John Wiley & Sons, Ltd.}, added-at = {2011-07-05T15:49:41.000+0200}, author = {Wildi-Tremblay, Philippe and Gosselin, Louis}, biburl = {https://www.bibsonomy.org/bibtex/276b3fb06ad4bbbfa12079e848fd6184a/thorade}, description = {Minimizing shell-and-tube heat exchanger cost with genetic algorithms and considering maintenance - Wildi-Tremblay - 2006 - International Journal of Energy Research - Wiley Online Library}, doi = {10.1002/er.1272}, interhash = {d83c3a18dae7e7b91770cb18800cce4c}, intrahash = {76b3fb06ad4bbbfa12079e848fd6184a}, issn = {1099-114X}, journal = {International Journal of Energy Research}, keywords = {2007 design economics heat-exchanger}, number = 9, pages = {867--885}, publisher = {John Wiley & Sons, Ltd.}, timestamp = {2011-07-05T15:49:41.000+0200}, title = {Minimizing shell-and-tube heat exchanger cost with genetic algorithms and considering maintenance}, url = {http://dx.doi.org/10.1002/er.1272}, volume = 31, year = 2007 }