Inter-plume aerodynamics for gasoline spray collapse

The collapse or merging of individual plumes of direct-injection gasoline injectors is of fundamental importance to engine performance because of its impact on fuel–air mixing. However, the mechanisms of spray collapse are not fully understood and are difficult to predict. The purpose of this work i...

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Veröffentlicht in:	International journal of engine research 2018-12, Vol.19 (10), p.1048-1067
Hauptverfasser:	Sphicas, Panos, Pickett, Lyle M, Skeen, Scott A, Frank, Jonathan H
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerodynamics Ambient temperature Collapse Fuel-air mixing Gas density Gasoline Injectors Particle image velocimetry Plumes Pressure vessels Vaporization Velocity measurement
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container_title	International journal of engine research
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creator	Sphicas, Panos Pickett, Lyle M Skeen, Scott A Frank, Jonathan H
description	The collapse or merging of individual plumes of direct-injection gasoline injectors is of fundamental importance to engine performance because of its impact on fuel–air mixing. However, the mechanisms of spray collapse are not fully understood and are difficult to predict. The purpose of this work is to study the aerodynamics in the inter-spray region, which can potentially lead to plume collapse. High-speed (100 kHz) particle image velocimetry is applied along a plane between plumes to observe the full temporal evolution of plume interaction and potential collapse, resolved for individual injection events. Supporting information along a line of sight is obtained using simultaneous diffused back illumination and Mie-scatter techniques. Experiments are performed under simulated engine conditions using a symmetric eight-hole injector in a high-temperature, high-pressure vessel at the “Spray G” operating conditions of the engine combustion network. Indicators of plume interaction and collapse include changes in counter-flow recirculation of ambient gas toward the injector along the axis of the injector or in the inter-plume region between plumes. The effect of ambient temperature and gas density on the inter-plume aerodynamics and the subsequent plume collapse are assessed. Increasing ambient temperature or density, with enhanced vaporization and momentum exchange, accelerates the plume interaction. Plume direction progressively shifts toward the injector axis with time, demonstrating that the plume interaction and collapse are inherently transient.
doi_str_mv	10.1177/1468087417740306
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The effect of ambient temperature and gas density on the inter-plume aerodynamics and the subsequent plume collapse are assessed. Increasing ambient temperature or density, with enhanced vaporization and momentum exchange, accelerates the plume interaction. 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The effect of ambient temperature and gas density on the inter-plume aerodynamics and the subsequent plume collapse are assessed. Increasing ambient temperature or density, with enhanced vaporization and momentum exchange, accelerates the plume interaction. Plume direction progressively shifts toward the injector axis with time, demonstrating that the plume interaction and collapse are inherently transient.</abstract><cop>London, England</cop><pub>SAGE Publications</pub><doi>10.1177/1468087417740306</doi><tpages>20</tpages><oa>free_for_read</oa></addata></record>
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subjects	Aerodynamics Ambient temperature Collapse Fuel-air mixing Gas density Gasoline Injectors Particle image velocimetry Plumes Pressure vessels Vaporization Velocity measurement
title	Inter-plume aerodynamics for gasoline spray collapse
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