Abstract
The purpose of this study is to investigate injection timing affected particle size distribution of a diesel engine fueled with biodiesel/diesel blends. The biodiesel blending ratios include 7, 10 and 20%vol. The experiments were operated at engine speed 1,500 rpm under 25, 50 and 75% engine loads and two different injection timing (25.5 CAD BTDC and 27.5 CAD BTDC). The effects of biodiesel addition and injection timing on the changes in black smoke and particle size distribution were discussed. Results showed that the standard injection timing for the addition of biodiesel, especially for 20% biodiesel blended with diesel fuel (B20) had a significant effect of increasing particle concentration and thus black smoke emission. The advanced injection timing for B20 could improve combustion efficiency and reduce small particles emission in nucleation-mode (Dp 5 – 50 nm) and particles in accumulation-mode (Dp 50 – 1,000 nm) became the smaller particle size, compared to standard and retarded injection timing. Moreover, the oxygen content in biodiesel could improve combustion efficiency and reduce the emission but it is necessary to modify the engine especially fuel injection timing.
Highlights
Nowadays, the popularity of compression ignition engines is growing in both the transportation and power generation sectors because of its high efficiency, fuel economy and durability compared to spark ignition engines [1,2]
Chiatti et al, [8] compared the results of the particles size distributions on an unmodified diesel engine using ultra-low sulfur diesel (ULSD) blended with biodiesel produced from waste cooking oil at ratios of 20 and 40% to standard ultra-low sulfur diesel fuel
The results of smoke emission and particle size distribution were considered under three different engine loads of 1,500 RPM engine speed
Summary
The popularity of compression ignition engines is growing in both the transportation and power generation sectors because of its high efficiency, fuel economy and durability compared to spark ignition engines [1,2]. Air pollution problems arise from combustion process of compression ignition engines, especially particulate matter (PM). Over the past few decades, researchers have studied the dust particle distribution. The diesel engine particulates in the exhaust gas are classified according to the particle diameter, which contains nucleation-mode particles Chiatti et al, [8] compared the results of the particles size distributions on an unmodified diesel engine using ultra-low sulfur diesel (ULSD) blended with biodiesel produced from waste cooking oil at ratios of 20 and 40% to standard ultra-low sulfur diesel fuel
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