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Портал Begell Электронная Бибилиотека e-Книги Журналы Справочники и Сборники статей Коллекции
International Journal of Fluid Mechanics Research
ESCI SJR: 0.206 SNIP: 0.446 CiteScore™: 0.5

ISSN Печать: 2152-5102
ISSN Онлайн: 2152-5110

Выпуски:
Том 46, 2019 Том 45, 2018 Том 44, 2017 Том 43, 2016 Том 42, 2015 Том 41, 2014 Том 40, 2013 Том 39, 2012 Том 38, 2011 Том 37, 2010 Том 36, 2009 Том 35, 2008 Том 34, 2007 Том 33, 2006 Том 32, 2005 Том 31, 2004 Том 30, 2003 Том 29, 2002 Том 28, 2001 Том 27, 2000 Том 26, 1999 Том 25, 1998 Том 24, 1997 Том 23, 1996 Том 22, 1995

International Journal of Fluid Mechanics Research

DOI: 10.1615/InterJFluidMechRes.v24.i4-6.300
pages 746-756

Numerical Study of Liquid Fuel Spray Characteristics

Zh. Liu
Gunma University, Gunma, Japan
Yi Liu
School of Aerospace, Tsinghua University, Beijing 100084, China
Masataka Arai
Division of Mechanical Science and Technology, Faculty of Science and Technology, Gunma University, 1-5-1 Tenjin-cho, Kiryu, Gunma, 376-8515, Japan; Tokyo Denki University
T. Obokata
Department of Mechanical System Engineering, Gunma University, 1-5-1, Tenjin, Kiryu, 376 Japan
Rolf D. Reitz
Engine Research Center, University of Wisconsin-Madison, Rm 1018A, 1500 Engineering Drive, Madison, Wisconsin 53706, USA

Краткое описание

The modified drop drag (MDD) model was further improved and implemented in the KIVA code for better describing the liquid fuel spray characteristics in diesel engine combustion chambers. The MDD model accounts for the effects of both the drop's frontal area and its drag coefficient as a function of its distortion on drop drag and drop breakup. The new version of the KIVA code with the MDD model was tested for the cases of the free liquid spray and the spray/wall impingement on a solid wall from single-hole fuel injection nozzles in high pressure chambers at room temperature condition. The results from numerical calculation by using the new version of KIVA code with the MDD model and the experimental data were in good agreement for both the free liquid spray and the spray/wall impingement cases. In addition, in the spray/wall impingement case the effect of the MDD model was seen to be very important on both the spray penetration and the wall spray height after impingement. In contrast to earlier models, it was found that the calculated data were insensitive to the choice of the breakup time constant, B1, after impingement. This indicates that the physics of drop destabilization processes following wall impingement are accounted for more reasonably with the MDD model.


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