This paper explores the use of a self-adaptive multipopulation elitist (SAMPE) Jaya algorithm for the economic optimization of shell-and-tube heat exchanger (STHE) design. Three different optimization problems of STHE are considered in this work. The same problems were earlier attempted by other researchers using genetic algorithm (GA), particle swarm optimization (PSO) algorithm, biogeography-based optimization (BBO), imperialist competitive algorithm (ICA), artificial bee colony (ABC), cuckoo-search algorithm (CSA), intelligence-tuned harmony search (ITHS), and cohort intelligence (CI) algorithm. The Jaya algorithm is a newly developed algorithm and it does not have any algorithmic-specific parameters to be tuned except the common control parameters of number of iterations and population size. The search mechanism of the Jaya algorithm is upgraded in this paper by using the multipopulation search scheme with the elitism. The SAMPE-Jaya algorithm is proposed in this paper to optimize the setup cost and operational cost of STHEs simultaneously. The performance of the proposed SAPME-Jaya algorithm is tested on four well-known constrained, ten unconstrained standard benchmark problems, and three STHE design optimization problems. The results of computational experiments proved the superiority of the proposed method over the latest reported methods used for the optimization of the same problems.
Issue Section:
Research Papers
References
1.
Yang
, J.
, Oh
, S. R.
, and Liu
, W.
, 2014
, “Optimization of Shell-and-Tube Heat Exchangers Using a General Design Approach Motivated by Constructal Theory
,” Int. J. Heat Mass Transfer
, 77
, pp. 1144
–1154
.2.
Yang
, J.
, Oh
, S. R.
, Liu
, W.
, and Jacobi
, A. M.
, 2014
, “Optimization of Shell-and-Tube Heat Exchangers Conforming to TEMA Standards With General Design Approach Motivated by Constructal Theory
,” Energy Convers. Manage.
, 78
, pp. 468
–476
.3.
Selbas
, O.
, Kızılkan
, M.
, and Reppich
, A.
, 2006
, “New Design Approach for Shell-and-Tube Heat Exchangers Using Genetic Algorithms From Economic Point of View
,” Chem. Eng. Process.: Process Intensif.
, 45
(4), pp. 268
–275
.4.
Selleri
, T.
, Najafi
, B.
, Rinaldi
, F.
, and Colombo
, G.
, 2013
, “Mathematical Modeling and Multi-Objective Optimization of a Mini-Channel Heat Exchanger Via Genetic Algorithm
,” ASME J. Therm. Sci. Eng. Appl.
, 5
(3
), p. 031013
.5.
Allen, B., Savard-Goguen, M., and Gosselin, L. 2009, “Optimizing Heat Exchanger Networks With Genetic Algorithms for Designing Each Heat Exchanger Including Condensers,”
Appl. Therm. Eng.
, 29(16), pp. 3437–3444. 6.
Fettaka
, S.
, Thibault
, J.
, and Gupta
, Y.
, 2013
, “Design of Shell-and-Tube Heat Exchangers Using Multiobjective Optimization
,” Int. J. Heat Mass Transfer
, 60
, pp. 343
–354
.7.
Ponce-Ortega
, J. M.
, Serna-Gonzalez
, M.
, and Jimenez-Gutierrez
, A.
, 2009
, “Use of Genetic Algorithms for the Optimal Design of Shell-and-Tube Heat Exchangers
,” Appl. Therm. Eng.
, 29
(2–3), pp. 203
–209
.8.
Luna–Abad
, J. P.
, and Alhama
, F.
, 2013
, “Design and Optimization of Composite Rectangular Fins Using the Relative Inverse Thermal Admittance
,” ASME J. Heat Transfer
, 135
(8
), p. 084504
.9.
Amini
, M.
, and Bazargan
, M.
, 2014, “Two Objective Optimization in Shell-and-Tube Heat Exchangers Using Genetic Algorithm
,” Appl. Therm. Eng.
, 69
(1–2), pp. 278
–285
.10.
Daroczy
, L.
, Janiga
, G.
, and Thevenin
, D.
, 2014
, “Systematic Analysis of the Heat Exchanger Arrangement Problem Using Multi-Objective Genetic Optimization
,” Energy
, 65
, pp. 364
–373
.11.
Khosravi
, R.
, Khosravi
, A.
, Nahavandi
, S.
, and Hajabdollah
, H.
, 2015
, “Effectiveness of Evolutionary Algorithms for Optimization of Heat Exchangers
,” Energy Convers. Manage.
, 89
, pp. 281
–288
.12.
Caputo
, A. C.
, Pelagagge
, P. M.
, and Salini
, P.
, 2008
, “Heat Exchanger Design Based on Economic Optimization
,” Appl. Therm. Eng.
, 28
(10), pp. 1151
–1159
.13.
Sanaye
, S.
, and Hajabdollahi
, H.
, 2010
, “Multi-Objective Optimization of Shell and Tube Heat Exchangers
,” Appl. Therm. Eng.
, 30
(14–15), pp. 1937
–1945
.14.
Wong
, J. Y. Q.
, Sharma
, S.
, and Rangaiah
, G. P.
, 2016
, “Design of Shell-and-Tube Heat Exchangers for Multiple Objectives Using Elitist Non-Dominated Sorting Genetic Algorithm With Termination Criteria
,” Appl. Therm. Eng.
, 93
, pp. 888
–899
.15.
Sadeghzadeh
, H.
, Ehyaei
, M. A.
, and Rosen
, M. A.
, 2015
, “Techno-Economic Optimization of a Shell and Tube Heat Exchanger by Genetic and Particle Swarm Algorithms
,” Energy Convers. Manage.
, 93
, pp. 84
–91
.16.
Ravagnani
, M. A. S. S.
, Silva
, A. P.
, Biscaiac
, E. C.
, and Caballero
, J. A.
, 2009
, “Optimal Design of Shell-and-Tube Heat Exchangers Using Particle Swarm Optimization
,” Ind. Eng. Chem. Res.
, 48
(6
), pp. 2927
–2935
.17.
Patel
, V. K.
, and Rao
, R. V.
, 2010
, “Design Optimization of Shell-and-Tube Heat Exchanger Using Particle Swarm Optimization Technique
,” Appl. Therm. Eng.
, 30
(11–12), pp. 1417
–1425
.18.
Mariani
, V. C.
, Duck
, A.
, Guerra
, F. A.
, Coelho
, L. S.
, and Rao
, R. V.
, 2012
, “Chaotic Quantum-Behaved Particle Swarm Approach Applied to Optimization of Heat Exchangers
,” Appl. Therm. Eng.
, 42
, pp. 119
–128
.19.
Sahin
, A. S.
, Kılıç
, B.
, and Kılıç
, U.
, 2011
, “Design and Economic Optimization of Shell and Tube Heat Exchangers Using Artificial Bee Colony (ABC) Algorithm
,” Energy Convers. Manage.
, 52
(11), pp. 3356
–3362
.20.
Hadidi
, A.
, Hadidi
, M.
, and Nazari
, A.
, 2013
, “A New Design Approach for Shell-and-Tube Heat Exchangers Using Imperialist Competitive Algorithm (ICA) From Economic Point of View
,” Energy Convers. Manage.
, 67
, pp. 66
–74
.21.
Hadidi
, A.
, and Nazari
, A.
, 2013
, “Design and Economic Optimization of Shell-and-Tube Heat Exchangers Using Biogeography-Based (BBO) Algorithm
,” Appl. Therm. Eng.
, 51
(1–2), pp. 1263
–1272
.22.
Asadi
, M.
, Song
, Y.
, Sunden
, B.
, and Xie
, G.
, 2014
, “Economic Optimization Design of Shell-and-Tube Heat Exchangers by a Cuckoo-Search-Algorithm
,” Appl. Therm. Eng.
, 73
(1), pp. 1032
–1040
.23.
Fesanghary
, M.
, Damangir
, E.
, and Soleimani
, I.
, 2009
, “Design Optimization of Shell and Tube Heat Exchangers Using Global Sensitivity Analysis and Harmony Search Algorithm
,” Appl. Therm. Eng.
, 29
(5–6), pp. 1026
–1031
.24.
Turgut
, O. E.
, Turgut
, M. S.
, and Coban
, M. T.
, 2014
, “Design and Economic Investigation of Shell and Tube Heat Exchangers Using Improved Intelligent Tuned Harmony Search Algorithm
,” Ain Shams Eng. J.
, 5
(4), pp. 1215
–1231
.25.
Mohanty
, D. K.
, 2016
, “Application of Firefly Algorithm for Design Optimization of a Shell and Tube Heat Exchanger From Economic Point of View
,” Int. J. Therm. Sci.
, 102
, pp. 228
–238
.26.
Rao
, R. V.
, and Patel
, V. K.
, 2013
, “Multi-Objective Optimization of Heat Exchangers Using a Modified Teaching–Learning-Based Optimization Algorithm
,” Appl. Math. Modell.
, 37
(3), pp. 1147
–1162
.27.
Ayala
, H. V. H.
, Keller
, P.
, Morais
, M. D. F.
, Mariani
, V. C.
, Coelho
, L. D. S.
, and Rao
, R. V.
, 2016
, “Design of Heat Exchangers Using a Novel Multiobjective Free Search Differential Evolution Paradigm
,” Appl. Therm. Eng.
, 94
, pp. 170
–177
.28.
Babu
, B. V.
, and Munawar
, S. A.
, 2007
, “Differential Evolution Strategies for Optimal Design Shell and Tube Heat Exchangers
,” Chem. Eng. Sci.
, 62
(14), pp. 3720
–3739
.29.
Rao
, R. V.
, 2016
, Teaching Learning Based Optimization Algorithm and Its Engineering Applications
, Springer Verlag
, London
.30.
Rao
, R. V.
, and Patel
, V. K.
, 2011
, “Optimization of Mechanical Draft Counter Flow Wet-Cooling Tower Using Artificial Bee Colony Algorithm
,” Energy Convers. Manage.
, 52
(7
), pp. 2611
–2622
.31.
Rao
, R. V.
, 2016
, “Jaya: A Simple and New Optimization Algorithm for Solving Constrained and Unconstrained Optimization Problems
,” Int. J. Ind. Eng. Comput.
, 7
(1
), pp. 19
–34
.32.
Cruz
, C.
, González
, J. R.
, and Pelta
, D. A.
, 2011
, “Optimization in Dynamic Environments: A Survey on Problems, Methods and Measures
,” Soft Comput.
, 15
(7
), pp. 1427
–1448
.33.
Branke
, J.
, Kaußler
, T.
, Schmidt
, C.
, and Schmeck
, H.
, 2000
, “A Multi-Population Approach to Dynamic Optimization Problems
,” Adaptive Computing in Design and Manufacturing
, Springer
, London, pp. 299
–308
.34.
Rao, R. V., and Saroj, A., 2017, “A Self-Adaptive Multi-Population Based Jaya Algorithm for Engineering Optimization,”
Swarm Evol. Compt.,
37, pp. 1–26. 35.
Chen
, D.
, and Zhao
, C.
, 2009
, “Particle Swarm Optimization With Adaptive Population Size and Its Application
,” Appl. Soft Comput.
, 9
(1), pp. 39
–48
.36.
Khalfe
, N. M.
, Lahiri
, S. K.
, and Wadhwa
, S. K.
, 2011
, “Simulated Annealing Technique to Design Minimum Cost Exchanger
,” CICEQ
, 17
(4
), pp. 409
–427
. 37.
Lahiri
, S. K.
, Khalfe
, N. M.
, and Wadhwa
, S. K.
, 2012
, “Particle Swarm Optimization Technique for the Optimal Design of Shell and Tube Heat Exchanger
,” Chem. Prod. Process Model.
, 7
(1
), pp. 289
–291
. 38.
Towler
, G.
, and Sinnott
, R.
, 2013
, Chemical Engineering Design: Principles, Practice and Economics of Plant and Process Design
, 2nd ed., Elsevier
, Boston, MA
.39.
Kern
, D. Q.
, 1950
, Process Heat Transfer
, McGraw-Hill Book Company
, Tokyo, Japan
.40.
Ngo
, T. T.
, Sadollahb
, A.
, and Kim
, J. H.
, 2016
, “A Cooperative Particle Swarm Optimizer With Stochastic Movements for Computationally Expensive Numerical Optimization Problems
,” J. Comput. Sci.
, 13
, pp. 68
–82
.41.
Dhaval
, S. V.
, Kulkarni
, A. J.
, Shastri
, A.
, and Kale
, I. R.
, 2016
, “Design and Economic Optimization of Shell-and-Tube Heat Exchanger Using Cohort Intelligence Algorithm
,” Neural Comput. Appl.
, epub.Copyright © 2018 by ASME
You do not currently have access to this content.
