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2021, vol. 19, br. 1, str. 246-251
Version of a mathematical model of purge ventilation system with a complex recuperative heat exchanger
(naslov ne postoji na srpskom)
aSouthwest State University, Faculty of Construction and Architecture, Department of Heat, Gas and Water Supply, Kursk, Russia
bSouthwest State University, Faculty of Construction and Architecture, Department of Higher Mathematics, Kursk, Russia

e-adresaejovvs@swsu.ru
Ključne reči: purge unit; utilization; heat transfer coefficient; electric power; efficiency; autonomy; ventilation gases; thermoelectricity
Sažetak
(ne postoji na srpskom)
The aim of the study is to develop a design of an air-heating recuperator for a purge ventilation system of a building inbuilt for the purpose of utilizing lower-grade heat from ventilation gases and emissions with the associated production of thermoelectricity. An experimental design of an air-heating recuperator as part of an experimental purge unit has been developed. It includes a thermoelectric source of electromotive difference, which operates as a result of the associated conversion of heat into electricity, which allows utilizing lower-potential heat of ventilation releases from 40°C to 60°C.
Reference
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Bulat, L.P. (2001) Thermoelectric cooling devices: Methodical instructions for students spec. 070200: Technique and physics of low temperatures. https://e.lanbook.com/book/43468
Changcun, L., Fengxing, J., Congcong, L., Wenfang, W., Xuejing, L., Tongzhou, W., Jingkun, X. (2017) A simple thermoelectric device based on inorganic/organic composite thin film for energy harvesting. Chemical Engineering Journal, 320: 201-210
Ding, L.C., Akbarzadeh, A., Tan, L. (2018) A review of power generation with thermoelectric system and its alternative with solar ponds. Renewable and Sustainable Energy Reviews, 81(81): 799-812
Ezhov, S.V., Evgenievna-Semicheva, N., Berezin, V.S., Vitalievna-Makhova, V., Burtsev, P.A., Brezhnev, V.A., Drozhzhin, S.R. (2017) Independent power supply source for the station of cathodic protection of pipelines against corrosion. Journal of Applied Engineering Science, vol. 15, br. 4, str. 501-505
Ezhov, V.S., Semicheva, N.E., Burtsev, A.P., Sokolov, S.M., Perepelitsa, N.S. (2019) Thermoelectric power supply source for a heat point. Patent of the Russian Federation, no. 2705348
Ezhov, V.S., Emelyanov, S.G., Dobroserdov, O.G., Ivanov, N.I., Semicheva, N.E., Burtsev, A.P. (2019) Autonomous air heater. Patent of the Russian Federation, no. 2705193
Ezhov, V.S., Semicheva, N.S., Burtsev, A.P., Ermakov, D.A., Perepelitsa, N.S. (2019) Development of experimental designs of the integrated heater for the disposal of low-potential waste heat of ventilation emissions. IOP Conference Series: Materials Science and Engineering, vol. 789, Issue 1, no. 0120202019, CIBv 2019
Kostuganov, A., Vytchikov, Y. (2017) On analysis of operating efficiency of autonomous ventilation systems. MATEC Web of Conferences, 117: 00087, XXVI RSP Seminar: Theoretical foundation of civil engineering, Warsaw, Poland
Kwan, T.H., Wu, X., Yao, Q. (2018) Multi-objective genetic optimization of the thermoelectric system for thermal management of proton exchange membrane fuel cells. Applied Energy, 217(217): 314-327
Saufi, S.M., Singh, B., Mohamed, W.A.N.W. (2019) Experimental and theoretical study of thermoelectric generator waste heat recovery model for an ultra-low temperature PEM fuel cell powered vehicle. Energy, 179(C): 628-646
Yezhov, V., Yemelianov, S., Semicheva, N., Berezin, S., Burtsev, A., Tolmachyova, V. (2015) Direct heat energy conversion into electrical energy: An experimental study. Journal of Applied Engineering Science, vol. 13, br. 4, str. 265-270
Yezhov, V., Semicheva, N., Pakhomova, E., Burtsev, A., Brezhnev, A., Perepelitsa, N. (2019) Characterization of thermoelectric generators for cathodic protection of pipelines of the city heating. u: Advances in Intelligent Systems and Computing: International Scientific Conference on Energy Management of Municipal Facilities and Sustainable Energy Technologies: EMMFT 2018, 983: 670-678
 

O članku

jezik rada: engleski
vrsta rada: izvorni naučni članak
DOI: 10.5937/jaes0-30068
primljen: 28.12.2020.
prihvaćen: 05.03.2021.
objavljen u SCIndeksu: 26.03.2021.
metod recenzije: dvostruko anoniman
Creative Commons License 4.0

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