Suppression of soot of a diesel engine fueled with biodiesel–diesel blends

Ni, Pei; Wei, Dapeng; Wang, Xiang-Li; Zhang, Dengpan; Zhong, Wang

doi:10.1002/ep.11962

Cited by 6 publications

(6 citation statements)

References 28 publications

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“…This is attributed by a wide consensus in literature to the biodiesel oxygen content, which improves the combustion in local fuel-rich regions in the chamber. The decrement aligns with the observations of other researchers [21,22]. Though that is the main reason, the widespread range of opacity reduction (from 25% to 47%) suggests that other fuel properties and/ or combustion parameters may affect the soot formationoxidation mechanisms in the cylinder.…”

Section: Engine Performancesupporting

confidence: 91%

Biofuels derived from Turkish industry wastes—a study of performance and emissions in a diesel engine

Altun

Rodríguez–Fernández

2015

Env Prog and Sustain Energy

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Recently, research has focused on the biofuel production from local industrial wastes due to the risk of greenhouse emissions derived from land-use change (both directly and indirectly) of conventional feedstock and the social concern about the effect of conventional biofuel production on oil prices and its availability (the so-called food vs. fuel debate). Therefore, with the aim to evaluate the use of biofuels derived from wastes from traditional manufacturing industries in Turkey, biodiesel fuels from leather fat, obtained as a by-product in the leather industry, waste anchovy fish oil, derived from the fish-processing industry, and waste frying cottonseed oil achieved from food industry, have been tested in a three-cylinder DI diesel engine at a steady-state condition. In a previous work, the viability of these fuels was evaluated by analyzing measured and estimated properties and indicators for main diesel emissions, and recommendations were made on their alternative use to conventional biodiesels with the benefit of potentially lower life-cycle greenhouse emissions. The experimental results, which were compared with ULSD operation, demonstrated that the engine performance was not significantly affected, while a substantial change in emissions was observed with the use of biofuels. In general, the emission results reported here are in a similar range to those obtained with the use of conventional biodiesel fuels. Nonetheless, the exact magnitude of these changes depended upon the biodiesel origin. Lubricity of alternative biofuels was also tested, revealing an enormous capacity for protecting the fuel system from wear, in line with conventional biodiesel fuels.

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Section: Engine Performancesupporting

confidence: 91%

Biofuels derived from Turkish industry wastes—a study of performance and emissions in a diesel engine

Altun

Rodríguez–Fernández

2015

Env Prog and Sustain Energy

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“…However, only a very small number of modelling studies have been performed for soot formation with biodiesel fuel. Ni et al [21] employs an empirical non-precursor model to estimate the soot volume fraction with the filter smoke number (FSN), based on the general purpose CFD software AVL-Fire for diesel engine tests. Arad et al [22] employed an empirical non-precursor model for the soot nucleation process.…”

Section: Introductionmentioning

confidence: 99%

Modelling of laminar diffusion flames with biodiesel blends and soot formation

Liu

Gao

Rigopoulos

et al. 2022

Fuel

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“…Diesel engines are extensively applied in transportation field and manufacturing industry due to their high thermal efficiency and reliable performance. However, diesel engines still have major problems of simultaneous reduce nitrogen oxide (NOx) and smoke emissions due to diffusion‐governing combustion mechanisms . Many new combustion modes such as homogenous charge compression ignition and dual‐fuel have been proposed to overcome this problem .…”

Section: Introductionmentioning

confidence: 99%

Effects of co‐combustion ratio on rapid combustion, cyclical variation, and emissions of a heavy‐duty diesel engine fueled with diesel‐methanol dual‐fuel

Zhang

2017

Env Prog and Sustain Energy

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Diesel-methanol dual-fuel (DMDF) combustion was achieved on a 6-cylinder, heavy-duty, turbocharged and common-rail diesel engine. In DMDF mode, the coalproduced methanol is induced to the upstream of the intake manifold and premixed with the fresh air to form a homogeneous methanol-air mixture and then ignited by directinjected pilot diesel in cylinder. The purpose of this study is to investigate the effects of co-combustion ratio (CCR) on the rapid combustion, cyclical variation and emissions of the DMDF engine. The experimental results show that CCR affect the rapid combustion (a) and knock tendency (b) greatly. With CCR increasing, both a and b increase significantly. The b exhibits an obviously large value under heavy load although CCR and a are small. At larger CCR, DMDF mode may generate a seriously cyclical variation and the coefficient of variation for indicated mean effective pressure (COV IMEP ) exhibits a relatively large value. However, with engine load increasing, the cyclical variation can be obviously decreased. It is also shown that both NOx and smoke emissions in DMDF mode present an obviously decrease trend, while CO and HC emissions exhibits an increase trend. A further reduction of NOx and smoke emissions can be obtained by increasing CCR, but CO and HC emissions are increased in this case.

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Suppression of soot of a diesel engine fueled with biodiesel–diesel blends

Cited by 6 publications

References 28 publications

Biofuels derived from Turkish industry wastes—a study of performance and emissions in a diesel engine

Biofuels derived from Turkish industry wastes—a study of performance and emissions in a diesel engine

Modelling of laminar diffusion flames with biodiesel blends and soot formation

Effects of co‐combustion ratio on rapid combustion, cyclical variation, and emissions of a heavy‐duty diesel engine fueled with diesel‐methanol dual‐fuel

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