Experimental Investigations on Dual-Fuel Engine Fueled with Tertiary Renewable Fuel Combinations of Biodiesel and Producer—Hydrogen Gas Using Response Surface Methodology

Halewadimath, S.S.; Banapurmath, N.R.; Yaliwal, V.S.; Gaitonde, V. N.; Khan, T. M. Yunus; Vadlamudi, Chandramouli; Krishnappa, Sanjay; Sajjan, Ashok M.

doi:10.3390/su15054483

Cited by 4 publications

(2 citation statements)

References 33 publications

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“…Halewadimath et al [24] varied the H 2 content in the inducted PG to improve the performance of DF engines using neem oil biodiesel blends. They noticed that in the presence of H 2 the ignition delay period was reduced with a decrease in combustion duration.…”

Section: Literature Reviewmentioning

confidence: 99%

Performance and engine exhaust study of a CI engine in dual fuel mode using diethyl ether as cetane enhancer additive

2023

IJATEE

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In this experiment, emission and performance analysis were conducted on a compression ignition (CI) engine operating with a blend of Karanja methyl ester and diesel as the pilot fuel. Diethyl ether (DEE) was used as a cetane enhancer to improve the brake thermal efficiency (BTE) of dual fuel (DF) engines. Producer gas (PG) was utilized to maximize diesel savings. The results show that BTE decreased in DF runs while using PG. However, when a 5% volume fraction of DEE was mixed with the selected pilot fuels, it led to an improvement in BTE during the DF run. The emission curves also reveal the positive impact of DEE on DF engine performance. Further investigation showed that a 10% volume fraction of Karanja methyl ester (B10) blended with diesel, when additionally mixed with 5% volume of DEE (referred to as 5DEE), achieved a BTE of 26% during DF mode operation with PG. In comparison, B10+PG, Diesel+PG, andDiesel+5DEE+PG reached BTEs of 23.75%, 24.2%, and 27.2%, respectively. Among these combinations, B10+5DEE+PG showed the highest reduction in smoke opacity (51.3%) and nitric oxide (54%) emissions during DF operation compared to the base results. Additionally, B10+5DEE+PG exhibited the lowest increase in hydrocarbon emissions (35.4%) compared to other DF operation combinations.

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Section: Literature Reviewmentioning

confidence: 99%

Performance and engine exhaust study of a CI engine in dual fuel mode using diethyl ether as cetane enhancer additive

2023

IJATEE

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“…Alina et al [22] used the RSM to optimize the extraction yield of biologically active compounds from crushed Merlot grapes using ultrasound treatment before maceration. Sushrut S. et al [23] optimized fuel flow rates in a DF engine using the RSM for improved brake thermal efficiency and reduced exhaust emissions. Allah et al [24] used the RSM to optimize the electrochemical disinfection of canal water using stainless steel electrodes and found that interelectrode spacing is the most significant factor affecting disinfection efficiency.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Swivel Spherical Hinge Structure Design Based on the Response Surface Method

et al. 2023

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The accurate analysis of key components of a spherical hinge structure directly affects bridge quality and safety during construction. Considering the key components of a spherical joint structure as the research object, a refined calculation model for the spherical joint is established to examine its stress using finite element analysis. The influence of design parameters on the mechanical characteristics of the spherical hinge structure is systematically analyzed. The response surface method (RSM), devised using a Box–Behnken design, is used to optimize the design of the spherical hinge structure parameters. A response surface model is established to derive the scheme of the optimized spherical hinge structure design. Moreover, by comparing the structural contact stress and rotational traction force before and after optimization, the effectiveness and necessity of the spherical hinge structure optimization are verified. The result comparison shows that the maximum contact stress and rotational traction force in the spherical hinge structure after optimization are reduced by 13.86% and 8.42%, respectively, compared with those before optimization. The relative error between the calculated and predicted values is approximately 3%, indicating that the RSM is feasible for optimizing key components of the spherical hinge structure. Its optimization effect is evident. Based on the identified optimal parameters of the spherical hinge structure, a range of recommended design parameters for the key structure of the rotating spherical hinge at different load carrying capacities is established using the interpolation method, which provides a valuable reference for engineering practice.

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From nickel–metal hydride batteries to advanced engines: A comprehensive review of hydrogen's role in the future energy landscape

Nivedhitha,

Banapurmath,

Yaliwal

et al. 2024

International Journal of Hydrogen Energy

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Experimental Investigations on Dual-Fuel Engine Fueled with Tertiary Renewable Fuel Combinations of Biodiesel and Producer—Hydrogen Gas Using Response Surface Methodology

Cited by 4 publications

References 33 publications

Performance and engine exhaust study of a CI engine in dual fuel mode using diethyl ether as cetane enhancer additive

Performance and engine exhaust study of a CI engine in dual fuel mode using diethyl ether as cetane enhancer additive

Optimization of Swivel Spherical Hinge Structure Design Based on the Response Surface Method

From nickel–metal hydride batteries to advanced engines: A comprehensive review of hydrogen's role in the future energy landscape

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