Tytuł artykułu
Autorzy
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Nowatorski elektrofiltr samozasysający (SE-ESP)
Języki publikacji
Abstrakty
n this paper, we presented a novel electrostatic precipitator (ESP) prototype. The operating mode and the components of the prototype were outlined in detail. Subsequently, three versions of the ESP were derived from the initially proposed basic model. These models were tested experimentally, and their method of procedure was validated through established simulations developed using COMSOL Multiphysics Software. Furthermore, the characteristics and efficiency of the electrostatic filtration of the three models were compared.
W tym artykule przedstawiliśmy nowy prototyp elektrofiltru (ESP). Szczegółowo nakreślono tryb pracy i komponenty prototypu. Następnie z pierwotnie proponowanego modelu podstawowego powstały trzy wersje ESP. Modele te zostały przetestowane eksperymentalnie, a ich metoda postępowania została zweryfikowana za pomocą ustalonych symulacji opracowanych przy użyciu oprogramowania COMSOL Multiphysics Software. Ponadto porównano właściwości i skuteczność filtracji elektrostatycznej trzech modeli.
Wydawca
Czasopismo
Rocznik
Tom
Strony
74--78
Opis fizyczny
Bibliogr. 22 poz., rys.
Twórcy
autor
- Laboratory of Electrical Engineering of Oran LGEO, Department of Electrical Engineering
autor
- Laboratory of Electrical Engineering of Oran LGEO, Department of Electrical Engineering
autor
- Laboratory of Electrical Engineering of Oran LGEO, Department of Electrical Engineering
autor
- Laboratory of Electrical Engineering of Oran LGEO, Department of Electrical Engineering
autor
- Laboratory of Electrical Engineering of Oran LGEO, Department of Electrical Engineering
- Faculty of Electrical Engineering, University of Sciences & Technology of Oran “Mohamed Boudiaf”, Oran, Algeria
Bibliografia
- [1] I. Manisalidis, E. Stavropoulou, A. Stavropoulos, E. Bezirtzoglou, Environmental and Health Impacts of Air Pollution: A review, J. Frontiers in Public Health, (Jan 17, 2020)
- [2] H. Ritchie, M. Roser, Air Pollution, Published online at OurWorldInData.org, (Oct 2017 &last revised in Nov 2019), (accessed Feb 20, 2020).
- [3] K. Chriscaden, N. Osseiran, WHO releases country estimates on air pollution exposure and health impact, Published online at WHO.int, (Sept 27, 2016), (accessed March 10, 2020)
- [4] EPA, OAR US, Why Indoor Air Quality is Important to Schools, Published online at epa.gov, (Oct 27, 2015), (accessed March 16, 2020)
- [5] WHO, Household air pollution and health, Published online at WHO.int, (May 8, 2018), (accessed Feb 24, 2020)
- [6] Royal College of Physicians, Every breath we take: the lifelong impact of air pollution, Report of a working party, (Feb 2016) London,
- [7] UNESCAP, Sand and Dust Storms in Asia and the Pacific: Opportunities for Regional Cooperation and Action, United Nations Publication, (2018)
- [8] N. Middleton, U. Kang, Sand and Dust Storms: Impact Mitigation, J. sustainability, (June 17, 2017)
- [9] EPA, OAR US, Particulate Matter (PM) Basics, published online at epa.gov, (updated on Oct 1, 2020)
- [10] D.E. Schraufnagel, The health effects of ultrafine particles, J. Experimental & Molecular Medecine, (March 17, 2020)
- [11] WHO, Health risks of particulate matter from long-range transboundary air pollution, Published WHO Regional Offie for Europe, Copenhagen (2006), Published euro.who.int
- [12] A. Karanasiou, N. Moreno, T. Moreno, M. Viana, F.de Leeuw, X. Querol, Health effects from Sahara dust episodes in Europe: Literature review and research gaps, J. Elsevier, (July 15, 2012)
- [13] M. Kotsyfakis, S.G. Zarogiannis, E. Patelarou, The health impact of Saharan Dust Exposure, IJOMEH, 32(6), (July16, 2019)
- [14] U.S. National Park Service, Where Does Air Pollution Come From? published at NPS.gov, (Last updated Jan 17, 2018), (accessed Apr 5, 2020)
- [15] B.G. Miller, 8-Particulate Formation and Control Technologies, J. Clean Coal Engineering Technology (Second Edition), Butterworth-Heinemann, p419-465, J. Elsevier, (Jan 6, 2017), ISBN 9780128113653
- [16] D. Kumar, D. Kumar, Chapter 12 – Dust Control, Sustainable Management of Coal Preparation, Woodhead Publishing, J. Elsevier, (Jun 8, 2018), p265-278, ISBN 9780128126325
- [17] J.H. Turner, P.A. Lawless, T. Yamamoto, D.W. Coy, J.D. McKenna, J.C. Mycock, A.B. Nunn, G.P. Greiner, J.D. McKenna, W.M. Vatavuk, Chapter 3-Electrostatic Precipitators, Section 6-Particulate Matter Controls, U.S. National (EPA), EPA/452/B-02-001, (Sept 1999)
- [18] I.V. Muralikrishna, V. Manickam, Chapter Fourteen – Air Pollution Control Technologies, (2017), p 337-397, Environmental Management, Butterworth-Heinemann, ISBN 9780128119891
- [19] P.C. Raynor, T.M. Peters, Chapter 7 - Controlling Nanoparticle Exposures, Assessing Nanoparticle Risks to Human Health (Second Edition), William Andrew Publishing, 2016, p 153-177, ISBN 9780323353236
- [20] L. Bäfver, J. Yngvesson, F. Niklasson, Residential Electrostatic Precipitator - Performance at efficient and poor combustion Conditions, SP Sveriges Tekniska Forskningsinstitut, Energiteknik, SP Rapport, Ind. Appl. IEEE Trans. 44 (2012), ISBN 978-91-87017-57-5, Borås
- [21] F.W. Peek, Dielectric Phenomena in High Voltage Engineering, McGraw-Hill Book Company, (1929)
- [22] Fariborz Haghighat, Ali Bahloul, Jaime Lara, Development of a Procedure to Measure the Effectiveness of N95 Respirator Filters against Nanoparticles, IRSST Québec and NanoQuébec, (July 2012)
Typ dokumentu
Bibliografia
Identyfikator YADDA
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