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Selection of the heat transfer coefficient using swarming algorithms

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The article presents the use of swarming algorithms in selecting the heat transfer coefficient, taking into account the boundary condition of the IV types. Numerical calculations were made using the proprietary TalyFEM program and classic form of swarming algorithms. A function was also used for the calculations, which, during the calculation, determined the error of the approximate solution and was minimalised using a pair of individually employed algorithms, namely artificial bee colony (ABC) and ant colony optimisation (ACO). The tests were carried out to select the heat transfer coefficient from one range. Describing the geometry for a mesh of 408 fine elements with 214 nodes, the research carried out presents two squares (one on top of the other) separated by a heat transfer layer with a κ coefficient. A type III boundary condition was established on the right and left of both edges. The upper and lower edges were isolated, and a type IV boundary condition with imperfect contact was established between the squares. Calculations were made for ABC and ACO, respectively, for populations equal to 20, 40 and 60 individuals and 2, 6 and 12 iterations. In addition, in each case, 0%, 1%, 2% and 5% noise of the reference values were also considered. The obtained results are satisfactory and very close to the reference values of the κ parameter. The obtained results demonstrate the possibility of using artificial intelligence (AI) algorithms to reconstruct the IV type boundary condition value during heat conduction modelling.
Rocznik
Strony
325--339
Opis fizyczny
Bibliogr. 24 poz., rys., tab., wykr.
Twórcy
  • Faculty of Mechanical Engineering and Computer Science, Czestochowa University of Technology, ul. Dąbrowskiego 73, 42-201 Częstochowa, Poland
autor
  • Faculty of Mechanical Engineering and Computer Science, Czestochowa University of Technology, ul. Dąbrowskiego 73, 42-201 Częstochowa, Poland
autor
  • Faculty of Mechanical Engineering and Computer Science, Czestochowa University of Technology, ul. Dąbrowskiego 73, 42-201 Częstochowa, Poland
  • Faculty of Mechatronics, Kazimierz Wielki University, ul. Kopernika 1, 85-074 Bydgoszcz, Poland
Bibliografia
  • 1. Gosselin L, Tye-Gingras M, Mathieu-Potvin F. Review of utilization of genetic algorithms in heat transfer problems. International Journal of Heat and Mass Transfer. 2009; 52(9-10):2169-2188.
  • 2. Kot V. Solution of the classical Stefan problem: Neumann condition. Journal of Engineering Physics and Thermophysics. 2017; 90(4): 889-917.
  • 3. Chen J, Yu W, Tian J, Chen L, Zhou Z. Image contrast enhancement using an artificial bee colony algorithm. Swarm and Evolutionary Computation. 2018; 38:287-294.
  • 4. Zhao X, Xuan D, Zhao K, Li Z. Elman neural network using ant colony optimization algorithm for estimating of state of charge of lithium-ion battery. Journal of Energy Storage. 2020; 32:101789.
  • 5. Karaboga D, Gorkemli B, Ozturk C, Karaboga N. A comprehensive survey: artificial bee colony (ABC) algorithm and applications. Artificial Intelligence Review. 2014; 42:21-57.
  • 6. Karaboga D. An idea based on honey bee swarm for numerical optimization. Technical Report. Kayseri/Türkiye: Erciyes University, Engineering Faculty, Computer Engineering Department; 2005. Report No.: TR-06.
  • 7. Karaboga D, Basturk B. On the performance of artificial bee colony (ABC) algorithm. Applied Soft Computing. 2008; 8(1):687-697.
  • 8. Hetmaniok E, Słota D, Zielonka A. Artificial Bee Colo-ny Algorithm Used for Reconstructing the Heat Flux Density in the Solidification Process. In International Conference on Artificial Intel-ligence and Soft Computing; 2014; 363–372.
  • 9. Hetmaniok E, Słota D, Zielonka A, Wituła R. Comparison of ABC and ACO Algorithms Applied for Solving the Inverse Heat Conduction Problem. In International Symposium on Swarm Intelligence and Differential Evolution; 2012; 249–257.
  • 10. Hetmaniok E, Słota D, Zielonka A. Restoration of the cooling conditions in a three-dimensional continuous casting process using AI algorithms. Applied Mathematical Modelling. 2015; 39(16): 4794-4807.
  • 11. Zielonka A, Hetmaniok E, Słota D. Inverse alloy solidification problem including the material phenomenon solved by using the bee algorithm. International Communications in Heat and Mass Transfer. 2017; 87:295-301.
  • 12. Grzymkowski R, Hetmaniok E, Słota D, Zielonka A. Application of the Ant Colony Optimization Algorithm in Solving the Inverse Stefan Problem. In Metal Forming; 2012; 1287-1290.
  • 13. Hetmaniok E, Słota D, Zielonka A. Application of the Swarm Intelligence Algorithm for Investigating the Inverse Continuous Casting Problem. Contemporary Challenges and Solutions in Applied Artificial Intelligence. 2013; 489: 157–162.
  • 14. Matsevityi YM, Alekhina SV, Borukhov VT. Identification of the thermal conductivity coefficient for quasi-stationary two-dimensional heat conduction equations. Journal of Engineering Physics and Thermophysics. 2017; 90(6):1295-1301.
  • 15. Tereshko V, Loengarov A. Collective decision-making in honey bee foraging dynamics. Computing and Information Systems. 2005; 9: 1-7.
  • 16. Colorni A, Dorigo M, Maniezzo V. Distributed Optimization by Ant Colonies. In Proceedings of the European Conference on Artificial Life; 1991; 134-142.
  • 17. Dorigo M, Maniezzo V, Colorni A. Ant system: Optimization by a colony of cooperating agents. IEEE Transactions on Systems, Man and Cybernetics, Part B (Cybernetics). 1996; 26(1):29-41.
  • 18. Dorigo M, Di Caro G. Ant colony optimization: a new meta-heuristic. In Proceedings of the 1999 Congress on Evolutionary Computation-CEC99; 1999;1470-1477.
  • 19. Geuzaine C, Remacle JF. GMSH: a three-dimensional finite element mesh generator with built-in pre- and post-processing facilities. International Journal for Numerical Methods in Engineering. 2009; 79(11):1309-1331.
  • 20. Dyja R, Grosser A. Oblicznia równoległe w symulacji krzepnięcia wykorzystującej model pośredni narstania fazy stałej. Modelowanie Inżynierskie. 2015; 24(55):21-26.
  • 21. Dyja R, Gawronska E, Grosser A, Jeruszka P, Sczygiol N. Estimate the Impact of Different Heat Capacity Approximation Methods on the Numerical Results During Computer Simulation of Solidification. Engineering Letters. 2016; 24(2):237-245.
  • 22. Kodali HK, Ganapathysubramanian B. A computational framework to investigate charge transport in heterogeneous organic photovoltaic devices. Computer Methods in Applied Mechanics and Engineering. 2012; 247:113-129.
  • 23. Balay S, Gropp WD, McInnes LC, Smith BF. Efficient Management of Parallelism in Object-Oriented Numerical Software Libraries. In Arge E,BAM,LHP. Modern Software Tools for Scientific Computing. Boston. 1997;163–202.
  • 24. Dyja R. Comparison of Results from In-House Solidification Convection Model with Standard Benchmark. Acta Physica Polonica. 2021; 139(5):525-528.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-5388a28f-d9b6-4063-a644-b8d76e5a3f7b
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