Faculty Publications

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Author: search.filters.author.Yadav, A.K.Subject: search.filters.subject.Direct injection

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    Combustion, performance, and tail pipe emissions of common rail diesel engine fueled with waste plastic oil-diesel blends
    (American Society of Mechanical Engineers (ASME) infocentral@asme.org, 2018) Lamani, V.T.; Yadav, A.K.; Kumar, G.N.
    The demand for plastic is eternally growing in urban areas and producing enormous quantity of plastic waste. The management and disposal of plastic waste have become a major concern worldwide. The awareness of waste to energy retrieval is one of the promising modes used for the treatment of the waste plastic. The present investigation evaluates the prospective use of waste plastic oil (WPO) as an alternative fuel for diesel engine. Different blends (WPO0, WPO30, and WPO50) with diesel are prepared on a volume basis and the engine is operated. Experiments are conducted for various injection timings (9 deg, 12 deg, 15 deg, and 18 deg BTDC) and for different exhaust gas recirculation (EGR) rates (0%, 10%, 15%, and 20%) at 100 MPa injection pressure. Combustion, performance, and tail pipe emissions of common rail direct injection (CRDI) engine are studied. The NOx, CO, and Soot emissions for waste plastic oil-diesel blends are found more than neat diesel. To reduce the NOx, EGR is employed, which results in reduction of NOx considerably, whereas other emissions, i.e., CO and Soot, get increased with increase in EGR rates. Soot for WPO-diesel blends is higher because of aromatic compounds present in plastic oils. Brake thermal efficiency (BTE) of blends is found to be higher compared to diesel. © 2018 by ASME.
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    Effect of bioethanol–diesel blends, exhaust gas recirculation rate and injection timing on performance, emission and combustion characteristics of a common rail diesel engine
    (Taylor and Francis Ltd. michael.wagreich@univie.ac.at, 2019) Lamani, V.T.; Baliga M, A.U.; Yadav, A.K.; Kumar, G.N.
    This investigation is focused on the effect of exhaust gas recirculation (EGR) and injection timing on the performance, combustion and exhaust emission characteristics of common rail direct injection (CRDI) engine fueled with bioethanol-blended diesel using computational fluid dynamics (CFD) simulation. Simulation is carried out for various EGR rates (0, 10, 20 and 30%), two different injection timings, and two different bioethanol–diesel blends (10 and 20%) at injection pressure. The equivalence ratio is kept constant in all the cases of bioethanol–diesel blends. The results indicate that the mean CO formation and ignition delay increase, whereas mean NO formation and in-cylinder temperature decrease, with increase in the EGR rate. Further, with an increase in percentage of the bioethanol blends, CO and soot formation decrease as compared to neat diesel. A significant increase in in-cylinder pressure (15%) is found at 14° before top dead centre (BTDC) compared to 9° BTDC, which leads to an increase in indicated thermal efficiency of 4% for neat diesel at 30% EGR. In the present study, maximum indicated thermal efficiency is obtained in the case of 10 and 20% bioethanol–diesel blend, and remains constant for all EGR rates considered in the study. Obtained results are validated with the available literature data and indicate good agreement. © 2017, © 2017 Informa UK Limited, trading as Taylor & Francis Group.
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    Extraction and characterization of coffee husk biodiesel and investigation of its effect on performance, combustion, and emission characteristics in a diesel engine
    (Elsevier Ltd, 2022) Emma, A.F.; Sathyabhama, A.; Yadav, A.K.
    Biodiesel and its blends with diesel are used in engines to overcome the problems of environmental pollution and fast depletion of conventional fuels. The purpose of this research is to extract oil from coffee husk, convert it into coffee husk oil methyl ester (CHOME) by transesterification, and test the suitability of this biodiesel as an alternate, renewable, sustainable fuel for a diesel engine. The physicochemical characteristics of the developed biodiesel are studied and compared with regular diesel. The results showed that the fundamental properties of the produced fuel are comparable to that of diesel. The performance, combustion, and emission characteristics of a diesel engine fueled with CHOME biodiesel are investigated. The experiments are conducted in a single-cylinder direct injection diesel engine at a constant speed by varying the loads (0, 25, 50, 75, and 100%) for different biodiesel-diesel blends (B10, B20, B30, B40, B50, and B80), and the results are compared with the baseline diesel. The brake thermal efficiency (BTE) of the blends, B10, B20, B30, and B50 dropped by 0.6, 0.7, 1.29, and 3%, respectively compared with the neat diesel. Similarly the brake specific energy consumption (BSEC) is reduced by 0.1, 0.3, 0.44, and 0.77% for B10, B20, B30, and B50, respectively. Exhaust gas emissions are reduced for all biodiesel-diesel blends. Compared to regular diesel, at full load, CO, HC, and smoke opacity of B30 reduced by 13.2%, 4%, and 12%, respectively. CO2 of B30 at full load is increased by 8.63%. In general, it can be stated that CHOME biodiesel is a promising alternate biodiesel that can be used in an internal combustion engine without major modifications. © 2022 The Authors
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    Biomass-derived 5-(tolylmethyl)furfural as a promising diesel additive: preparation, process scale-up, and engine studies
    (Royal Society of Chemistry, 2025) Yadav, A.K.; Yadav, S.K.; Kumar, G.N.; Madav, V.; Dutta, S.
    Furanic fuel oxygenates, renewably produced from biomass, have received significant interest in lessening dependence on petroleum-derived liquid fuels and reducing emissions. 5-(Tolylmethyl)furfural (TMF) was prepared by the Friedel-Crafts reaction between cellulose-derived 5-(acetoxymethyl)furfural (AcMF) and petroleum-derived toluene. The process was optimized on various parameters, such as reaction temperature, molar ratio of reagents, catalyst loading, and duration. Anhydrous ZnCl2 was the best catalyst for the reaction, affording a 67% isolated yield of TMF under optimized conditions (120 °C, 4 h). TMF was prepared on a 30 g scale and blended (1-5 vol%) with diesel. The physicochemical properties of the TMF-diesel blended fuel mixtures were studied, and then they were employed as fuel for a direct injection single-cylinder diesel engine. The results show good fuel properties and reduced emissions compared to unblended diesel fuel. © 2025 The Royal Society of Chemistry.