Effect of injection timing of waste plastic oil and its blends on CRDI diesel engine

Kumar, Amit; Pali, Harveer Singh; Kumar, Manoj

doi:10.1177/14680874221119131

Cited by 7 publications

(5 citation statements)

References 49 publications

(59 reference statements)

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“…According to the studies by Balat et al [8] and Fayad et al [9], biodiesel can be produced from more than 350 oil-bearing crops, including soybeans, castor beans, sunflowers, rapeseed, peanuts, and cottonseed, each constituting potential alternatives for fossil fuel. Kumar et al [10] investigated the effect of waste plastic oil (WPO) blends and variable injection timing on engine performance and emissions in a CRDI diesel engine. They found that the optimal BTE is 6.7% at a 17 • bTDC injection interval, and that the emissions of NO X and CO decreased by 2.15% and 16%, respectively, via the combustion of WPO compared to diesel.…”

Section: Introductionmentioning

confidence: 99%

Reducing Soot Nanoparticles and NOX Emissions in CRDI Diesel Engine by Incorporating TiO2 Nano-Additives into Biodiesel Blends and Using High Rate of EGR

Fayad

Sobhi²,

Chaichan

et al. 2023

Energies

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The developments in the field of nano-additives have increased in the recent years due to the desire to reduce the level of exhaust emissions in diesel engines. The soot characteristics of particulate matter (PM) and nitrogen oxides (NOX) were experimentally investigated using two concentrations of titanium dioxide (TiO2) as nano-additives (25 ppm and 40 ppm) blended with C20D (composed of 20% castor oil methyl ester and 80% diesel fuel) and 30% exhaust gas recirculation (EGR). The combustion of C20D + TiO2 increases brake thermal efficiency (BTE) by 2.8% in comparison with neat C20D, while a significant reduction was obtained in BSFC 6.5% and NOX emissions were maintained at a level parallel with diesel. The results indicated that the technique involving a high EGR rate and the addition of 25 ppm and 40 ppm of TiO2 nanoparticles to the C20D exhibits better reductions in NOX emissions by 17.34% and 21.83%, respectively, compared to the technique comprising the use of C20D + TiO2 and C20D. The reduction in the total concentration of PM via the addition of TiO2 nanoparticles to the C20D was 26.74% greater than neat C20D and diesel. In contrast, the incorporation of a high rate of EGR with C20D +TiO2 increased the PM concentrations by 16.85% compared to the technique without EGR. Furthermore, the high concentrations of TiO2 nanoparticles (40 ppm) in the C20D produced 19 nm smaller soot nanoparticles compared to the 23 nm larger soot nanoparticles produced from the low concentrations of TiO2 nanoparticles (25 ppm) added into the C20D. The current investigation reveals that the reduction in NOX emissions and the production of soot nanoparticles notably improved due to the synergic effect of EGR, the TiO2 nanoparticles, and biodiesel.

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Section: Introductionmentioning

confidence: 99%

Reducing Soot Nanoparticles and NOX Emissions in CRDI Diesel Engine by Incorporating TiO2 Nano-Additives into Biodiesel Blends and Using High Rate of EGR

Fayad

Sobhi²,

Chaichan

et al. 2023

Energies

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“…It has been used for further research and scientific papers in the field of diesel engine processes [7]. Similar procedures of experimental determination of injection parameters, due to their crucial influence on working processes in engine cylinders, were also applied by other researchers [8][9][10][11][12][13][14][15][16]. Comparative experimental results of in-cylinder pressure flow and injection parameters in direct injection diesel engines are shown in [8], where standard diesel fuel and emulsion of water and diesel fuel are used.…”

Section: Introductionmentioning

confidence: 99%

“…The effect of experimentally determined injection pressures on performance, power and fuel consumption in direct injection diesel engines is discussed in detail in [11], [13] and [15]. Calculated process parameters of the injection of a medium-speed diesel engine using a computer program developed for this purpose successfully corresponded to the measured [12], and in [14] it was experimentally proven that oils obtained from waste plastic may have similar injection characteristics to petroleum-based diesel fuel. By experimental determination of the pilot injection times, main injection quantities and times, combined with mathematical models of fuel dispersion, combustion and exhaust emissions, it was possible to determine the influence of the mentioned parameters on performance, noise and exhaust emissions of diesel engines [16].…”

Section: Introductionmentioning

confidence: 99%

Testing high-pressure pumps on the BOSCH test bench

Bulatović,

Knežević,

Biočanin

et al. 2024

Engineering Today

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This paper presents the procedure for testing high-pressure inline pumps for special-purpose engine in laboratory conditions. The original methodology and procedure for determining the injection pressure at the beginning and end of the high-pressure pipe, as well as the needle lift of the injector elements for a given number of camshaft pump rotations, are described. The injection parameter trends for three pump elements are also shown. The aim of the paper is to describe in detail the developed methods and acquired experiences in order to standardize them, making them permanently available to researchers dealing with this issue.

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“…Research findings suggest that incorporating plastic oil into diesel engines can enhance performance and diminish emissions. A study conducted by Kumar et al [3] illustrated that substituting 20% plastic oil for diesel resulted in a 6.7% increase in Brake Thermal Efficiency (BTE) and lowered NOx and CO emissions by 2.15% and 16%, respectively. Mustayen et al [4] observed notable improvements in torque and horsepower when utilizing plastic oil in diesel engines.…”

Section: Introductionmentioning

confidence: 99%

Influence of Fuel Injection Timing and Hydrogen Enrichment on Waste Plastic Oil: Performance, Combustion, and Emissions Analysis

Anand,

Debbarma

2024

DDF

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The escalating global demand for fossil fuels, coupled with geopolitical uncertainties, underscores the imperative for alternative fuels in internal combustion engines. Simultaneously, the pressing issue of plastic waste disposal necessitates sustainable solutions. This research delves into the impact of hydrogen enrichment on a CRDI-diesel engine using diesel and waste plastic oil, varying fuel injection timing (23, 25, and 27) °CA bTDC at 400 bar fuel injection pressure. The addition of hydrogen at 4 lpm improves Brake Thermal Efficiency (BTE) and lowers Brake Specific Fuel Consumption (BSFC), resulting in reduced hydrocarbons (HC) and carbon monoxide (CO) emissions, though Exhaust Gas Temperature (EGT) and NOx emissions increase. The WPO10+4H2 blend at 25 °CA bTDC demonstrates an 8.7% BTE increase, a 10.5% BSFC reduction at full load, and substantial decreases in HC and CO emissions compared to diesel. Despite these advantages, NOx emissions increase by 8% compared to pure diesel. Hydrogen integration in CRDI engines enhances performance and addresses sustainability, while waste plastic oil in diesel engines repurposes plastic waste, reduces fossil fuel dependency, and supports a circular economy with energy recovery.

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Effect of injection timing of waste plastic oil and its blends on CRDI diesel engine

Cited by 7 publications

References 49 publications

Reducing Soot Nanoparticles and NOX Emissions in CRDI Diesel Engine by Incorporating TiO2 Nano-Additives into Biodiesel Blends and Using High Rate of EGR

Reducing Soot Nanoparticles and NOX Emissions in CRDI Diesel Engine by Incorporating TiO2 Nano-Additives into Biodiesel Blends and Using High Rate of EGR

Testing high-pressure pumps on the BOSCH test bench

Influence of Fuel Injection Timing and Hydrogen Enrichment on Waste Plastic Oil: Performance, Combustion, and Emissions Analysis

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