Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The paper presents an analysis of the design of air cleaners in performance vehicles. The paper confirms that their fundamental property is a much lower flow resistance compared to standard air cleaners. The consequences of replacing a standard air filter element with a performance one have been described. The impact of this modification i.e. an increase (decrease) in the engine torque and power output has been shown. A need to perform tests related to the filtration properties of performance air cleaners has been indicated. A methodology of laboratory research has been developed for performance vehicle air cleaners. The results of the research on the filtration efficiency and accuracy characteristics have been presented along with the flow resistance of air filter elements/air cleaners depending on the dust absorbance coefficient km. The accuracy of the filter element has been evaluated following a Pamas particle counter measurement.
Czasopismo
Rocznik
Tom
Strony
25--34
Opis fizyczny
Bibliogr. 34 poz., wykr.
Twórcy
autor
- Faculty of Mechanics Military University of Technology, Warsaw, Poland
Bibliografia
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- [2] BUCHER, T.M., TAFRESHI, H.V., TEPPER, G.C., Modeling performance of thinfibrous coatings with orthogonally layered nanofibers for improved aerosol filtration. Powder Technology. 2013, 249, 43-53.
- [3] CHŁOPEK, Z. Testing of hazards to the environment caused by particulate matter during use of vehicles. Eksploatacja i Niezawodność – Maintenance and Reliability. 2012, 2, 160-170.
- [4] Diesel Engine Air Filtration. PALL Corporation. 2004.
- [5] DURST, M., KLEIN, G., MOSER, N. Filtration in Fahrzeugen. Die Bibliothek der Technik, Niemcy 2005.
- [6] DZIUBAK, T. Operating fluids contaminantions and their effect on the wear of elements of a motor vehicle’s combustion engine. The Archives of Automotive Engineering – Archiwum motoryzacji. 2016, 72(2), 43-72.
- [7] DZIUBAK, T., SZWEDKOWICZ, S. Experimental research on filtering fibers in a cyclone–porous barrier system. Combustion Engines. 2014, 158(3), 45-55.
- [8] DZIUBAK, T. The assessment of the possibilities of improvement of the extraction evenness in multicyclone dedusters fitted in special vehicles. Combustion Engines. 2012, 4, 34-42.
- [9] DZIUBAK, T. Methodology of research of filter paper characteristics to air filter of vehicle exploited at large air dustiness conditions. ZEM PAN. 2003, 4(136), 101-117.
- [10] ERDMANNSDÖRFER, H. Lesttingmoglichkeiten von Papierfiltern zur Reinigung der Ansaugluft von Diselmotoren. MTZ. 1971, 32(4), 123-131.
- [11] FITCH, J. Clean oil reduces engine fuel consumption. Practicing Oil Analysis Magazine. 2002, 11-12.
- [12] MULLER, T.K., MEYER, J., THEBAULT, E. et al. Dust capacity increase of air filters by oil pre-treatment. Aerosol Technology. 2014.
- [13] GRAFE, T., GOGINS, M., BARRIS, M. et al. Nanofibers in filtration applications in transportation. Filtration 2001 International Conference and Exposition. Chicago, Illinois, December 3-5, 2001.
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- [16] HEIKKILÄ, P., SIPILÄ, A., PELTOLA, M. et al. Electrospun PA-66 Coating on Textile Surfaces. Textile Research Journal. 2007, 77(11), 864-870.
- [17] JAROSZCZYK, T., FALLON, S.L., DORGAN, J.E. et al. Development of high dust capacity multi-media engine air filters. Fluid/Particle Separation Journal. 2003, 15(2), 57-65.
- [18] JAROSZCZYK, T., FALLON, S.L., PARDUE, B.A. Analysis of engine air cleaner efficiency for different size dust distributions. Fluid/Particle Separation Journal. 2002, 14(2), 75-88.
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- [22] PN-S-34040, Filtry powietrza. Wymagania i badania. PKN, 1996.
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- [25] MYSŁOWSKI, J. Doładowanie silników. WKiŁ, Warszawa 2011.
- [26] TRUHAN, J. Filter performance as the engine sees it. Filtration & Separation. 1997, 34(12), 1019-1022.
- [27] WANG, Q., BAI, Y., XIE, J. et al. Synthesis and filtration properties of polyimide nanofiber membrane/carbon woven fabric sandwiched hot gas filters for removal of PM 2.5 particles. Powder Technology. 2016, 292, 54-63.
- [28] www.bmcairfilters.com.
- [29] www.K&Nfilters.com.
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- [33] www.google.pl/search?q=filtr+stożkowy+osłony+gorącego+powietrza&rlz=1C1CAFB_enPL683PL683&espv=2&biw=1280&bih=894&tbm=isch&tbo=u&source=univ&sa=X&ved=0ahUKEwjimeD8jKbSAhWD2CwKHeS8BlgQsAQIGQ&dpr=1.
- [34] www.google.pl/search?q=filtry+stożkowe&oq=filtry+stożkowe&aqs=chrome.0.69i59j0l5.9375j0j8&sourceid=chrome&ie=UTF-8#q=filtry+sto%C5%BCkowe+bmc&*.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-0232f40a-dd70-42ff-974d-2cb70814d7ab