Quantitative Characterization of Near-Field Fuel Sprays by Multi-Orifice Direct Injection Using Uitrafast X-Tomography Technique

A low-pressure direct injection fuel system for spark ignition direct injection engines has been developed, in which a high-turbulence nozzle technology was employed to achieve fine fuel droplet size at a low injection pressure around 2 MPa. It is particularly important to study spray characteristic...

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Bibliographic Details
Published in:SAE transactions 2006-01, Vol.115, p.576-583
Main Authors: Liu, Xin, Im, Kyoung-Su, Wang, Yujie, Wang, Jin, Hung, David L.S., Winkelman, James R., Tate, Mark W., Ercan, Alper, Koerner, Lucas J., Caswell, Thomas, Chamberlain, Darol, Schuette, Daniel R., Philipp, Hugh, Smilgies, Detlef M., Gruner, Sol M.
Format: Article
Language:English
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Summary:A low-pressure direct injection fuel system for spark ignition direct injection engines has been developed, in which a high-turbulence nozzle technology was employed to achieve fine fuel droplet size at a low injection pressure around 2 MPa. It is particularly important to study spray characteristics in the nearnozzle region due to the immediate liquid breakup at the nozzle exit. By using an uitrafast x-ray area detector and intense synchrotron x-ray beams, the interior structure and dynamics of the direct injection gasoline sprays from a multi-orifice turbulence-assisted nozzle were elucidated for the first time in a highly quantitative manner with ps-temporal resolution. Revealed by a newly developed, uitrafast computed x-microtomography technique, many detailed features associated with the transient liquid flows are readily observable in the reconstructed spray. Furthermore, an accurate 3dimensional fuel density distribution, in the form of fuel volume fraction, was obtained by the time-resolved computed tomography. The time-dependent fuel density distribution revealed that the fuel jet is well broken up immediately at the nozzle exits. These results not only reveal the near-field characteristics of the partial atomized fuel sprays with unprecedented detail, but also facilitate the development of an advanced multi-orifice direct injector. This uitrafast tomography capability also will facilitate the realistic computational fluid dynamic simulations in highly transient and multiphase fuel spray systems.
ISSN:0096-736X
2577-1531