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    A comprehensive review on the applicability of hydrogen and natural gas as gaseous fuel for dual fuel engine operation
    (Taylor & Francis Inc, 2024) Singh, Paramvir; Balasubramanian, Dhinesh; Venugopal, Inbanaathan Papla; Tyagi, Vineet Veer; Goel, Varun; Wae-Hayee, Makatar; Kalam, Mohammed Abdul
    Hydrogen and natural gas are promising alternatives to fossil fuels in combustion engines for sustainable environment. Consumption of fossil fuels is a matter of growing concern that needs to be dealt with seriously for a sustainable, better tomorrow as fossil fuels have dreadful implications on the environment. Therefore, there is an urgent need across the globe to quest for environment-friendly alternative fuels, which can power internal combustion engines. Moreover, regulated and unregulated emissions from engines have been affecting human health and the environment. In this review article, hydrogen in combination with natural gas along with diesel as a pilot fuel is investigated. The impactsof exhaust gas recirculation with hydrogen and natural gas are also discussed. It is observed from the review that an H2 proportion of up to 5-30% is beneficial in combination with natural gas as well with other alternative fuels. The further increase in the hydrogen proportion create the problem of backfiring, knocking as well as increasing the NOx emissions. The transportation and storage are the biggest problems with the hydrogen fuel. Among the alternatives, gaseous fuels have great importance, and they need proper attention for inclusion in the CI engine as a fuel used in dual-fuel mode.
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    Engine behavior analysis on a conventional diesel engine combustion mode powered by low viscous cedarwood oil/waste cooking oil biodiesel/diesel fuel mixture - An experimental study
    (Elsevier, 2024) Nguyen, Van Nhanh; Balasubramanian, Dhinesh; Rajarajan, Amudhan; Venugopal, Inbanaathan Papla; Dineshkumar, C.; Ravikumar, R.; Le, Duc Trong Nguyen
    Binary biofuel is the best alternative source that completely replaces petroleum -based fuel. In this study, we have experimented with the waste cooking oil and cedarwood oil as biofuel in a DI CI engine for various proportions and related its combustion, emission, and performance characteristics to those of base diesel. This study aims to eliminate the utilization of fossil fuel in a diesel engine by introducing green binary fuel (low viscous fuel resulting from the blending of cedarwood oil with WCO biodiesel) successfully. The objective of the study is to convert cedarwood - WCO into green binary fuel and investigate its performance, emission, and combustion properties. The transesterification process is utilized for the enhancement of WCO as biodiesel. It occasioned a reduction in brake thermal efficiency as the addition of waste cooking oil in the blend increased. At the same time, the maximum value of BTE of 27.8% was attained for B10C90 (10% transesterified waste cooking oil and 90% cedarwood oil in volume), whereas it was 28.1% for diesel at maximum load conditions. The BSEC was 15.4 MJ/kW-hr for B10C90 and 12.8 MJ/kWhr for diesel. The emission characteristics, CO, HC, NOx, CO2, and smoke for B10C90 were 17.93 g/kWhr, 0.55 g/kWhr., 20.09 g/kWhr, 2210.9 g/kWhr, and 25.55%. Combustion features such as NHRR, burn duration, MPRR, combustion efficiency, Ignition delay, and coefficient of variance for B10C90 were 53.74 bar, 29.38 CAD, 4.71 bar/CAD, 99.7%, 7.01 CAD, and 4.73% respectively. It showed that B10C90 had comparable performance (BTE) and combustion values to mineral diesel with better emission characteristics.
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    Enhancing the performance of renewable biogas powered engine employing oxyhydrogen: Optimization with desirability and D-optimal design
    (Elsevier Sci Ltd, 2023) Sharma, Prabhakar; Balasubramanian, Dhinesh; Khai, Chu Thanh; Venugopal, Inbanaathan Papla; Alruqi, Mansoor; Josephin, J. S. Femilda; Sonthalia, Ankit
    The performance and exhaust characteristics of a dual-fuel compression ignition engine were explored, with biogas as the primary fuel, diesel as the pilot-injected fuel, and oxyhydrogen as the fortifying agent. The trials were carried out with the use of an RSM-based D-optimal design. ANOVA was used to create the relationship functions between input and output. Except for nitrogen oxide emissions, oxyhydrogen fortification increased biogas-diesel engine combustion and decreased carbon-based pollutants. For each result, RSM-ANOVA was utilized to generate mathematical formulations (models). The output of the models was predicted and compared to the observed findings. The prediction models showed robust prediction efficiency (R2 greater than 99.21%). The optimal engine operating parameters were discovered by desirability approach-based optimization to be 24 degrees crank angles before the top dead center, 10.88 kg engine loading, and 1.1 lpm oxyhydrogen flow rate. All outcomes were within 3.75% of the model's predicted output when the optimized parameters were tested experimentally. The current research has the potential to be widely used in compression ignition engine-based transportation systems.