Investigation of performance and emissions of diesel engine run on biodiesel produced from karanja oil in a single-step transesterification process using heterogeneous catalyst (lithium-impregnated calcium oxide)

References

• Zbarcea O, Scarpete D, Vrabie V, et al., 2016 Environmental pollutions by diesel engine. Part II : a literature review regarding HC, CO, CO2 and soot emissions, Termonetica, suppliment. 65–69.
   Google Scholar
• Balat M. Prospects for worldwide Biodiesel market development. Energ Source Part B Econ Planning Policy. 2009;4:48–58.
   Google Scholar
• Barnwal BK, Sharma MP. Prospectus of biodiesel production from vegetable oil in India. Renew Sustain Energy Rev. 2005;9:363–378.
   Google Scholar
• Das D, Pathak V, Yadav AS, et al., 2016 Evaluation of performance, emission and combustion characteristics of diesel engine fueled with castor biodiesel. Biofuels, 7269, 1–9.
   Google Scholar
• Dharmadhikari HM, Kumar PR, Rao SS. Performance and emissions of C. I. engine using blends of biodiesel and diesel at different injection pressures. Int J Appl Res Mech Eng. 2012, 2/2;1–6.
   Google Scholar
• Chokri B, Ridha E, Rachid S, et al. Experimental study of a diesel engine performance running on waste vegetable oil biodiesel blend. J Energy Resour Technol. 2012;134:032202.
   Google Scholar
• Bobade SN, Khyade VB. Detail study on the properties of pongamia pinnata (Karanja) for the production of biofuel. Res J Chem Sci. 2012;2:16–20.
   Google Scholar
• Dwivedi G, Sharma MP, 2014. Prospects of biodiesel from Pongamia in India. Renew Sustain Energy Rev., 32, 114–122.
   Google Scholar
• Prakash N, Jose AA, Devanesan MG, et al. Optimization of Karanja oil transesterification. Indian J Chem Technol. 2006;13:505–509.
   Google Scholar
• Khayoon MS, Olutoye MA, Hameed BH, 2012. Utilization of crude karanj (Pongamia pinnata) oil as a potential feedstock for the synthesis of fatty acid methyl esters. Bioresour Technol., 111, 175–179.
   Google Scholar
• Sharma YC, Singh B. Development of biodiesel from Karanja, a tree found in rural India. Fuel. 2008;87:1740–1742.
   Google Scholar
• Naik M, Meher LC, Naik SN, et al. Production of biodiesel from high free fatty acid Karanja (Pongamia Pinnata) oil. Biomass and Bioenergy. 2008;32:354–357.
   Google Scholar
• Patil PD, Deng S. Optimization of biodiesel production from edible and non-edible vegetable oils. Fuel. 2009;88:1302–1306.
   Google Scholar
• Gangil S, Mewar C, Singh RK, et al. Influence of acid catalyst on two step transesterification of Karanja oil with high free fatty acids. Biofuels [Internet]. 2015;6:377–381.
   Google Scholar
• Chauhan BS, Kumar N, Cho HM, et al. Astudy of performance and emission of adiesel engine fueled with Karanja biodiesel and its blends. Energy. 2013;56:1–7.
   Google Scholar
• Borges ME, Díaz L, 2012. Recent developments on heterogeneous catalysts for biodiesel production by oil esterification and transesterification reactions: a review. Renew Sustain Energy Rev., 16, 2839–2849.
   Google Scholar
• Endalew AK, Kiros Y, Zanzi R, 2011. Heterogeneous catalysis for biodiesel production from Jatropha curcas oil (JCO). Energy, 36, 5, 2693–2700.
   Google Scholar
• yoki. Heterogeneous catalysis for biodiesel production. 2010. 1–10. Available from: http://www.kth.se/polopoly_fs/1.187900!/Menu/general/column-content/attachment/15.pdf%5Cnpapers3://publication/uuid/317FD5AF-CF30-46AE-B3C1-92F8D0AB9B60
   Google Scholar
• Singh V, Hameed BH, Sharma YC, 2016. Economically viable production of biodiesel from a rural feedstock from Eastern India, P. pinnata oil using a recyclable laboratory synthesized heterogeneous catalyst. Energy Convers Manag., 122, 52–62.
   Google Scholar
• Thiruvengadaravi K V., Nandagopal J, Baskaralingam P, et al., 2012 Acid-catalyzed esterification of karanja (Pongamia pinnata) oil with high free fatty acids for biodiesel production. Fuel, 98, 1–4.
   Google Scholar
• Karmee S, Chadha A. Preparation of biodiesel from crude oil of Pongamia Pinnata. BioResour Technol. 2005;96:1425–1429.
   Google Scholar
• Kouzu M, Hidaka J-S. Transesterification of vegetable oil into BD catalyzed by CaO: a review. Fuel. 2012;93:1–12.
   Google Scholar
• Granados ML, Alonso DM, Alba-Rubio AC, et al. Transesterification of triglycerides by CaO: increase of the reaction rate by biodiesel addition. Energy Fuels. 2009;23:2259–2263.
   Google Scholar
• Meher LC, Kulkarni MG, Dalai AK, et al. Transesterification of Karanja (Pongamia Pinnata) oil by solid basic catalysts. Eur J Lipis Sci Technol. 2006;108:389–397.
   Google Scholar
• Kumar D, Ali A. Nanocrystalline lithium ion impregnated calcium oxide as heterogeneous catalyst for transesterification of high moisture containing cotton seed oil. Energy Fuels. 2010;24:2091–2097.
   Google Scholar
• Anjana PA, Niju S, Begum KMMS, et al., 2016 Studies on biodiesel production from Pongamia oil using heterogeneous catalyst and its effect on diesel engine performance and emission characteristics. Biofuels, 7, 4, 377–387.
   Google Scholar
• Qadri SB, Skelton EF, Hsu D, et al. size induced transition temperature reduction in nano particles of ZnSr. Phys Rev. 1999;60:9191–9193.
   Google Scholar
• Sinha D, Murugavelh S. Biodiesel production from waste cotton seed oil using low cost catalyst: engine performance and emission characteristics. Perspect Sci [Internet]. 2016;8:1–4.
   Google Scholar
• Panneerselvam N, Murugesan A, Porkodi KP, et al. Computational engine performance and emission analysis using Ceiba pentandra biodiesel. Biofuels [Internet]. 2016;7269:1–9.
   Google Scholar
• Dhar A, Kevin R, Agarwal AK, 2012. Production of biodiesel from high-FFA neem oil and its performance, emission and combustion characterization in a single cylinder DICI engine. Fuel Process Technol., 97, 118–129.
   Google Scholar
• Behçet R, 2011. Performance and emission study of waste anchovy fish biodiesel in a diesel engine. Fuel Process Technol, 92, 6, 1187–1194.
   Google Scholar
• Serin H, Akar NY. The performance and emissions of a diesel engine fueled with tea seed (camellia sinensis) oil biodiesel-diesel fuel blends. Int J Green Energy. 2014;11:292–301.
   Google Scholar
• Raheman H, Phadatare AG. Diesel engine emissions and performance from blends of karanja methyl ester and diesel. Biomass Bioenerg. 2004;27:393–397.
   Google Scholar
• Hira A, Das D. Performance and emission evaluation of diesel engine fuelled with biodiesel produced from high free fatty acid crude soyabean oil. 2016, Biofuel; 7269, 1–9.
   Google Scholar
• Taylor P, Aydin H, İlkiliç C, 2015. Energy Sources, Part A : Recovery, Utilization, and Environmental Effects Exhaust Emissions of a CI Engine Operated with Biodiesel from Rapeseed Oil Exhaust Emissions of a CI Engine Operated with Biodiesel from Rapeseed Oil 37–41.
   Google Scholar
• Usta N. Combustion of biodiesel fuel produced from hazelnut soapstock / waste sunflower oil mixture in a Diesel engine, Energy conversion and Management. 2005;46:741–755.
   Google Scholar
• Wang WG. Emissions from nine heavy trucks fueled by diesel and biodiesel blend without engine modification. Environ Sci Technol. 2000;34:933–939.
   Google Scholar
• Schumacher LG. Heavy-duty engine exhaust emis- sion tests using methyl ester soybean oil/diesel fuel blends. Bioresour Technol. 1996;57:31–36.
   Google Scholar
• Xue J, Grift TE, Hansen AC. Effect of biodiesel on engine performances and emissions. Renew Sust Energ Rev. 2011;15:1098–1116.
   Google Scholar
• Khan K, Kumar G, Sharma AK, et al. Performance and emission characteristics of a diesel engine using complementary blending of castor and karanja biodiesel. Biofuels [Internet]. 2016;7269:1–8.
   Google Scholar