Abstract
A series of tests were carried out to assess the environmental effects of biodiesel blends made of different vegetable oil, such as corn, sunflower, and palm, on exhaust and noise diesel engine emissions. Biodiesel blends with 20% vegetable oil biodiesel and 80% diesel fuel by volume were developed. The tests were conducted in a stationary diesel engine test bed consisting of a single-cylinder, four-stroke, and direct injection engine at variable engine speed. A prediction framework in terms of polynomial regression (PR) was first adopted to determine the correlation between the independent variables (engine speed, fuel type) and the dependent variables (exhaust emissions, noise level, and brake thermal efficiency). After that, a regression model was optimized by the grey wolf optimization (GWO) algorithm to update the current positions of the population in the discrete searching space, resulting in the optimal engine speed and fuel type for lower exhaust and noise emissions and maximizing engine performance. The following conclusions were drawn from the experimental and optimization results: in general, the emissions of unburned hydrocarbon (UHC), carbon dioxide (CO2), and carbon monoxide (CO) from all the different types of biodiesel blends were lower than those of diesel fuel. In contrast, the concentration of nitrogen oxides (NOx) emitted by all the types of biodiesel blends increased. The noise level produced by all the forms of biodiesel, especially palm biodiesel fuel, was lowered when compared to pure diesel. All the tested fuels had a high noise level in the middle frequency band, at 75% engine load, and high engine speeds. On average, the proposed PR-GWO model exhibited remarkable predictive reliability, with a high square of correlation coefficient (R2) of 0.9823 and a low root mean square error (RMSE) of 0.0177. Finally, the proposed model achieved superior outcomes, which may be utilized to predict and maximize engine performance and minimize exhaust and noise emissions.
Highlights
The interest in sustainable, eco–friendly, and renewable fuels has been growing as a result of environmental degradation from environmental pollution and the limited supply of conventional petroleum [1,2,3]
The results showed a reduction in HC, carbon monoxide (CO), nitrogen oxides (NOx), and noise emissions compared to pure diesel and biodiesel fuels that were not hydrogen-enriched
The emissions of CO, CO2, NOx, unburned hydrocarbon emission (UHC), and noise were minimized and the brake thermal efficiency (BTE) was maximized using a combination of polynomial regression (PR) model with
Summary
The interest in sustainable, eco–friendly, and renewable fuels has been growing as a result of environmental degradation from environmental pollution and the limited supply of conventional petroleum [1,2,3]. Many combustion technologies, such as dual-fuel [7], partially premixed combustion (PPC) [8], advanced combustion system with optimized bowl and innovative fuel injection system [9], improved fuel injection [10], and employed exhaust gas recirculation (EGR). The authors remarked that the reduction in carbon monoxide, particulate matter, unburned hydrocarbon, and nitrogen oxide emissions compared to pure diesel blends were achieved. Fattah et al [15] concluded that palm biodiesel fuel could dramatically reduce the HC and CO emissions by up to 50% compared to neat diesel fuel. The results revealed that the combined blends of palm and jatropha biodiesel have a slightly higher brake specific fuel consumption rather than that of pure diesel. The acoustic emission was reduced in the range of 2.5% to 5% depending on blend ratios ranging from 5 to 10 by volume, respectively
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