THERMOECONOMIC OPTIMIZATION NUMERICAL METHOD OF VENTILATION UNITS WITH RECUPERATIVE HEAT EXCHANGERS
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Abstract
A thermoeconomic optimization method of ventilation units with recuperative heat exchangers is proposed, which allows comparing the efficiency indicators of recuperative heat exchangers with different designs of the heat exchange surface. It is noted that it is inexpedient to select a single generalized optimality criterion and derive an analytical expression for it due to the need to take into account a large amount of discretely changing factors and introduce restrictions to them.
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References
Kafarov, V.V., Meshalkin, V.P. & Gur'eva, L.V. (1988). Optimizatsiya teploobmennykh protsessov i sistem. Moscow: Energoatomizdat. (In Russ.).
Zafataev, V.A. (2012). Postanovka i reshenie optimizatsionnoi zadachi kalorifernoi ustanovki na osnove eksergoekonomicheskogo metoda [Formulation and solution of the optimization problem of a heating unit based on the exergo-economic method]. Vestn. Polots. gos. un-ta. Ser. F, Str-vo. Priklad. nauki [Herald of Polotsk State University. Series F. Civil engineering. Аppliеd Sciences], (16), 93–101. (In Russ., abstr. in Engl.).
Hancharou, E.I. & Zafatayeu, V.A. (2010). Exergy application limits. European & National Dimension in Research: materials of the conference / Novopolotsk (28–29 apr. 2010 g.) (69–71). Novopolotsk: Polotsk State University.
Karaliova, T.I. & Zafatayeu, V.A. (2010). Thermo-economic optimization theory application to heat exchange process. European & National Dimension in Research: materials of the conference / Novopolotsk (27–28 apr. 2011 g.) (66–69). Novopolotsk: Polotsk State University.
Lapidus, A.S. (1986). Ekonomicheskaya optimizatsiya khimicheskikh proizvodstv. Moscow: Khimiya. (In Russ.).
Nitch, R. (1968). K eksergeticheskoi teorii formirovaniya zatrat. In V.M. Brodyanski (Eds.). Energiya i eksergiya: sb. st. (94–105). Moscow: Mir. (In Russ.).
Boyarinov, A.I. & Kafarov, V.V. (1969). Metody optimizatsii v khimicheskoi tekhnologii. Moscow: Khimiya. (In Russ.).
Ibrić, N., Fu, C., & Gundersen, T. (2024). Simultaneous Optimization of Work and Heat Exchange Networks. Energies, 17(7). DOI: 10.3390/en17071753.
Popyrin, L.S. (1978). Matematicheskoe modelirovanie i optimizatsiya teploenergeticheskikh ustanovok. Moscow: Energiya. (In Russ.).
Boiko, E.A. (2001). Primenenie EVM dlya resheniya teploenergeticheskikh zadach. Krasnoyarsk: Sib. promysel. (In Russ.).
Onosovskii, V.V. (1990). Modelirovanie i optimizatsiya kholodil'nykh ustanovok. Leningrad: Izd-vo LU. (In Russ.).
Andryushchenko, A.I. (1974). Optimizatsiya teplovykh tsiklov i protsessov TES. Moscow: Vyssh. shk. (In Russ.).
Jiang, H., Jiang, T., Tian, H., Wu, Q., Deng, C., & Zhang, R. (2024). Heat Transfer Simulation and Structural Optimization of Spiral Fin-and-Tube Heat Exchanger. Electronics, 13(23). DOI: 10.3390/electronics13234639.
Farzin, A., Mehran, S., & Salmalian, K. (2024). Thermodynamic and Economic Optimization of Plate-Fin Heat Exchangers Using the Grasshopper Optimization Algorithm. International Journal of Thermodynamics, 27(2), 1–9. DOI: 10.5541/ijot.1285479.
Kanevets, G.E. (1979). Obobshchennye metody rascheta teploobmennikov. Kyiv: Navuk. dumka. (In Russ.).
Byalyi, B.I. (2005). Teplomassoobmennoe oborudovanie vozdukhoobrabatyvayushchikh ustanovok OOO «VEZA». Moscow: Infort. (In Russ.).
Bazhan, P.I., Kanevets, G.E. & Seliverstov, V.M. (1989). Spravochnik po teploobmennym apparatam. Moscow: Mashinostroenie. (In Russ.).
Sousa, D.L. & Balmant, W. (2024). Parametric evaluation of heat recovery in a recuperative heat exchanger. Revista De Engenharia Térmica, 22(3), 25–33. DOI: 10.5380/reterm.v22i3.94668
Zafataev, V.A. (2015). Vybor geometricheskogo ispolneniya profil'nogo lista orebreniya dlya vozdukhopodogrevatelei iz trub. Arkhitektura, Stroitel'stvo, Transport: sb. materialov Mezhdunar. NPK / Omsk (2–3 dek. 2015 г.) (258–263). Omsk: Sib. gos. avtomob.-dorozh. akademiya. (In Russ.).
Koroleva, T.I., & Zafataev, V.A. (2018). Termodinamicheskoe obosnovanie utilizatsii teploty dymovykh gazov v kondensatsionnykh teploutilizatorakh na primere kotel'noi «5-i polk» g. Vitebska. In A.A. Bakatovich (Eds.) & L.M. Parfenova (Eds.). Arkhitekturno-stroitel'nyi kompleks: Problemy, Perspektivy, Innovatsii: elektron. sb. st. Mezhdunar. nauch. konf., posvyashch. 50-letiyu Polots.gos. un-ta. Novopolotsk: Polotsk State University (418–425). (In Russ.).
Koroleva, T.I., & Zafataev, V.A. (2016). Proverka usloviya kondensatsii vlagi v vozdushnom teploutilizatore rekuperativnogo tipa.Stroitel'stvo-2016: sb. materialov II Bryanskogo mezhdunar. innov. foruma / Bryansk (1 Dek. 2016 g.), T. 2 (51–54). Bryansk:Bryan. gos. inzhener.-tekhnol. un-t. (In Russ.)
Zafataev, V.A. (2016). Opredelenie vozmozhnosti kondensatsii vlagi v vozdushnom plastinchatom utilizatore teploty rekuperativnogo tipa. Innovatsionnye tekhnologii v promyshlennosti: obrazovanie, nauka, proizvodstvo: sbornik materialov vserossiiskoi nauchno-prakticheskoi konferentsii / Sterlitamak (16 dek. 2016g.) (326–328). Sterlitamak: Ufim. gos. neftyanoi tekhn. un-t. FilialFGBOU VO UGNTU v g. Sterlitamake. (In Russ.).