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Effects of split injection strategies on evaporation dynamics and combustion performance: Role of first injection mass ratio in soot and NOx reduction

Weiwei Shang, Haizhao Li, Kang Yang, Haotian Qi and Keiya Nishida

Energy, 2025, vol. 332, issue C

Abstract: This study systematically investigates the effects of single and split diesel injection strategies on fuel-air mixing, evaporation, and combustion performance in a 2D piston cavity. Through laser absorption scattering (LAS) and two-color techniques, the injection rate, spray tip penetration, liquid/vapor-phase distribution, ignition timing (IT), and emissions characteristics were analyzed across four strategies: S160 (single injection) and D160_25:75, D160_50:50, D160_75:25 (split with 25 %, 50 %, and 75 % first-stage mass ratios, respectively). Results demonstrate that split injection significantly enhances fuel evaporation efficiency compared to single injection, while simultaneously reducing NOx and soot. The D160_75:25 strategy demonstrated optimal performance by achieving the highest vapor-phase homogeneity—as quantified through vapor-phase concentration distribution analysis (ranking: D160_75:25 > D160_25:75 > D160_50:50)—along with reduced wall-film formation and minimized NOx-soot trade-offs. Critical thresholds for ignition (vapor concentration >0.8 mg/cm3) and soot formation (>1 mg/cm3) were identified. The 75 % first-stage injection ratio emerged as the most balanced approach, improving combustion efficiency while aligning with tightening emission regulations. This work establishes a mechanistic framework for designing split injection systems that enhance energy conversion efficiency in diesel engines, offering a pragmatic pathway for decarbonizing non-electrified transport sectors.

Keywords: Split injection; Spray-wall interaction; Vapor-phase threshold; NOx-soot trade-off; Emission-intensity reduction (search for similar items in EconPapers)
Date: 2025
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Persistent link: https://EconPapers.repec.org/RePEc:eee:energy:v:332:y:2025:i:c:s0360544225028567

DOI: 10.1016/j.energy.2025.137214

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