Experimental and statistical assessment for Hydrogen-powered dual-fuel diesel engine using a novel biodiesel blend at variable injection pressure
Akshay Jain, Bhaskor Jyoti Bora, Rakesh Kumar, Prabhakar Sharma, Debabrata Barik, Bhaskar Jyoti Medhi, Ümit Ağbulut
Abstract
• Achieved 85% Liquid Fuel Replacement with Biodiesel-Hydrogen Blend. • Optimised the Dual-Fuel Engine for 28.11% Efficiency. • Reducing Emissions: CO and HC Decreased by 9.27% and 47.61%, respectively. • Both Efficiency and Emissions Breakthrough with Hydrogen Blend. Hydrogen has been proven to be a potential fuel alternative in the area of field of transportation and power generation. The study aimed to improve the efficiency of a dual-fuel engine running on a blend of biodiesels and hydrogen by optimizing operating parameters. This involved varying the injection pressure of pilot fuel (220, 240, and 260 bar) and adjusting engine load (ranging from 20% to 100% in increments of 20% in five steps). The results indicate that maximum brake thermal efficiency of 28.11 % and liquid fuel substitution by 85% when the injection pressure of pilot fuel was set to 240 bar at 100 % engine load. At 100% load, setting the injection pressure of fuel to 240 bar resulted in a substantial drop in the emissions of carbon monoxide and hydrocarbons by 9.27% and 47.61%, respectively. The response surface methodology specified that the optimized value of the engine load and pilot fuel injection pressure was found to be 55.93% and 242.731 bar, respectively for achieving optimum results of response variables from the engine.