Effect of Cross-Flow Velocity on Fuel Adhesion of Flat-Wall Impinging Spray under Triple Stage Split Injection

Penghua Shi; Nguyen Binh Trong; Youichi Ogata; Keiya Nishida; Gengxin Zhang; Hongliang Luo

doi:10.4271/2023-32-0013

Effect of Cross-Flow Velocity on Fuel Adhesion of Flat-Wall Impinging Spray under Triple Stage Split Injection

Penghua Shi, Nguyen Binh Trong, Youichi Ogata, Keiya Nishida, Gengxin Zhang^*, Hongliang Luo

^*Corresponding author for this work

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

The high injection pressure and small cylinder volume of direct injection spark ignition (DISI) engines can result in flat-wall wetness on the surface of the piston, increasing fuel consumption and pollutant emissions. The characteristics of microscopic fuel adhesion are observed using refractive index matching (RIM). Fuel adhesion characteristics after wall impingement are evaluated with various cross-flow velocities under triple stage injection conditions. The results indicate that cross-flow has a beneficial effect on the diffusion of fuel spray. Average fuel adhesion thickness decreases with an increase in cross-flow velocities. Furthermore, cross-flow promotes the evaporation of fuel adhesion, which leads to a reduction in the fuel adhesion mass/mass ratio. The improvement of injection strategy has guidance on low-carbon future.

Original language	English
Article number	2023-32-0013
Number of pages	10
Journal	SAE Technical Papers
Volume	2023
DOIs	https://doi.org/10.4271/2023-32-0013
Publication status	Published - 29 Sept 2023

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title = "Effect of Cross-Flow Velocity on Fuel Adhesion of Flat-Wall Impinging Spray under Triple Stage Split Injection",

abstract = "The high injection pressure and small cylinder volume of direct injection spark ignition (DISI) engines can result in flat-wall wetness on the surface of the piston, increasing fuel consumption and pollutant emissions. The characteristics of microscopic fuel adhesion are observed using refractive index matching (RIM). Fuel adhesion characteristics after wall impingement are evaluated with various cross-flow velocities under triple stage injection conditions. The results indicate that cross-flow has a beneficial effect on the diffusion of fuel spray. Average fuel adhesion thickness decreases with an increase in cross-flow velocities. Furthermore, cross-flow promotes the evaporation of fuel adhesion, which leads to a reduction in the fuel adhesion mass/mass ratio. The improvement of injection strategy has guidance on low-carbon future.",

author = "Penghua Shi and Trong, {Nguyen Binh} and Youichi Ogata and Keiya Nishida and Gengxin Zhang and Hongliang Luo",

year = "2023",

month = sep,

day = "29",

doi = "10.4271/2023-32-0013",

language = "English",

volume = "2023",

journal = "SAE Technical Papers",

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T1 - Effect of Cross-Flow Velocity on Fuel Adhesion of Flat-Wall Impinging Spray under Triple Stage Split Injection

AU - Shi, Penghua

AU - Trong, Nguyen Binh

AU - Ogata, Youichi

AU - Nishida, Keiya

AU - Zhang, Gengxin

AU - Luo, Hongliang

PY - 2023/9/29

Y1 - 2023/9/29

N2 - The high injection pressure and small cylinder volume of direct injection spark ignition (DISI) engines can result in flat-wall wetness on the surface of the piston, increasing fuel consumption and pollutant emissions. The characteristics of microscopic fuel adhesion are observed using refractive index matching (RIM). Fuel adhesion characteristics after wall impingement are evaluated with various cross-flow velocities under triple stage injection conditions. The results indicate that cross-flow has a beneficial effect on the diffusion of fuel spray. Average fuel adhesion thickness decreases with an increase in cross-flow velocities. Furthermore, cross-flow promotes the evaporation of fuel adhesion, which leads to a reduction in the fuel adhesion mass/mass ratio. The improvement of injection strategy has guidance on low-carbon future.

AB - The high injection pressure and small cylinder volume of direct injection spark ignition (DISI) engines can result in flat-wall wetness on the surface of the piston, increasing fuel consumption and pollutant emissions. The characteristics of microscopic fuel adhesion are observed using refractive index matching (RIM). Fuel adhesion characteristics after wall impingement are evaluated with various cross-flow velocities under triple stage injection conditions. The results indicate that cross-flow has a beneficial effect on the diffusion of fuel spray. Average fuel adhesion thickness decreases with an increase in cross-flow velocities. Furthermore, cross-flow promotes the evaporation of fuel adhesion, which leads to a reduction in the fuel adhesion mass/mass ratio. The improvement of injection strategy has guidance on low-carbon future.

U2 - 10.4271/2023-32-0013

DO - 10.4271/2023-32-0013

M3 - Article

SN - 0148-7191

VL - 2023

JO - SAE Technical Papers

JF - SAE Technical Papers

M1 - 2023-32-0013

ER -

Effect of Cross-Flow Velocity on Fuel Adhesion of Flat-Wall Impinging Spray under Triple Stage Split Injection

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