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Energies 2019, 12, 809 40 of 41 221. Taylor,C.F.TheInternalCombustionEngineinTheoryandPracticeVol.1,2nded.;MITPress:Cambridge,MA, USA, 1985. 222. Heywood,J.B.InternalCombustionEngineFundamentals,1sted.;McGraw-HillEducation:NewYork,NY, USA, 1988. 223. Reif, K. Diesel Engine Management—Systems and Components, 1st ed.; Springer Vieweg: Kranzberg, Germany, 2014. 224. Caton, P.A.; Williams, S.A.; Kamin, R.A.; Luning-Prak, D.; Hamilton, L.J.; Cowart, J.S. Hydrotreated algae renewable fuel performance in a military diesel engine. In Proceedings of the ASME 2012 Internal Combustion Engine Division Spring Technical Conference, Torino, Italy, 6–9 May 2012; pp. 121–132. 225. Petersen,J.;Seivwright,D.;Caton,P.;Millsaps,K.Combustioncharacterizationandignitiondelaymodeling of low and high-cetane alternative diesel fuels in a marine diesel engine. Energy Fuel. 2014, 28, 5463–5471. [CrossRef] 226. Ogunkoya,D.;Roberts,W.L.;Fang,T.;Thapaliya,N.Investigationoftheeffectsofrenewabledieselfuelson engine performance, combustion, and emissions. Fuel 2015, 140, 541–554. [CrossRef] 227. Mangus,M.;Mattson,J.;Depcik,C.Performanceandemissionscharacteristicsofhydroprocessedrenewable jet fuel blends in a single-cylinder compression ignition engine with electronically controlled fuel injection. Combust. Sci. Technol. 2015, 187, 857–873. [CrossRef] 228. Zubel,M.;Bhardwaj,O.P.;Heuser,B.;Holderbaum,B.;Doerr,S.;Nuottimäki,J.Advancedfuelformulation approach using blends of paraffinic and oxygenated biofuels: Analysis of emission reduction potential in a high efficiency diesel combustion system. SAE Int. J. Fuels Lubr. 2016, 9, 481–492. [CrossRef] 229. Mattson,J.M.S.;Depcik,C.Firstandsecondlawheatreleaseanalysisinasinglecylinderengine.SAEInt.J. Engines 2016, 9, 536–545. [CrossRef] 230. Kumar,V.;Sindhu,R.K.;Kumar,S.Comparativeanalysisofgreendieselversuspetro-dieselincompression ignition engine. Biosci. Biotechnol. Res. Commun. 2018, 11, 128–135. 231. Aatola,H.;Larmi,M.;Sarjovaara,T.;Mikkonen,S.Hydrotreatedvegetableoil(HVO)asarenewablediesel fuel: Trade-off between NOx, particulate emission, and fuel consumption of a heavy duty engine. SAE Int. J. Engines 2008, 1, 1251–1262. [CrossRef] 232. Sugiyama,K.;Goto,I.;Kitano,K.;Mogi,K.;Honkanen,M.Effectsofhydrotreatedvegetableoil(HVO)as renewable diesel fuel on combustion and exhaust emissions in diesel engine. SAE Int. J. Fuels Lubr. 2011, 5, 205–217. [CrossRef] 233. Armas,O.;García-Contreras,R.;Ramos,A.;López,A.F.Impactofanimalfatbiodiesel,GTL,andHVOfuels on combustion, performance, and pollutant emissions of a light-duty diesel vehicle tested under the NEDC. J. Energy Eng. 2015, 141. [CrossRef] 234. Drenth,A.C.;Olsen,D.B.;Cabot,P.E.;Johnson,J.J.Compressionignitionengineperformanceandemission evaluation of industrial oilseed biofuel feedstocks camelina, carinata, and pennycress across three fuel pathways. Fuel 2014, 136, 143–155. [CrossRef] 235. Kim,D.;Kim,S.;Oh,S.;No,S.Y.Engineperformanceandemissioncharacteristicsofhydrotreatedvegetable oil in light duty diesel engines. Fuel 2014, 125, 36–43. [CrossRef] 236. Murtonen, T.; Aakko-Saksa, P.; Kuronen, M.; Mikkonen, S.; Lehtoranta, K. Emissions with heavy-duty diesel engines and vehicles using FAME, HVO and GTL fuels with and without DOC + POC aftertreatment. SAE Int. J. Fuels Lubr. 2009, 2, 147–166. [CrossRef] 237. Singh,D.;Subramanian,K.A.;Singal,S.K.Emissionsandfuelconsumptioncharacteristicsofaheavyduty diesel engine fueled with hydroprocessed renewable diesel and biodiesel. Appl. Energy 2015, 155, 440–446. [CrossRef] 238. Karavalakis, G.; Jiang, Y.; Yang, J.; Durbin, T.; Nuottimäki, J.; Lehto, K. Emissions and fuel economy evaluation from two current technology heavy-duty trucks operated on HVO and FAME blends. SAE Int. J. Fuels Lubr. 2016, 9, 177–190. [CrossRef] 239. Erkkila,K.;Nylund,N.O.;Hulkkonen,T.;Tilli,A.;Mikkonen,S.;Saikkonen,P.;Makinen,R.;Amberla,A. Emission performance of paraffinic HVO diesel fuel in heavy duty vehicles. SAE Int. 2011. [CrossRef] 240. Hajbabaei, M.; Johnson, K.C.; Okamoto, R.A.; Mitchell, A.; Pullman, M.; Durbin, T.D. Evaluation of the impacts of biodiesel and second generation biofuels on NOx emissions for CARB diesel fuels. Environ. Sci. Technol. 2012, 46, 9163–9173. [CrossRef] [PubMed]PDF Image | Green Diesel: Biomass Feedstocks, Production Technologies
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