Exergo-Environmental Optimization of a Diesel Engine

ARDABILI, S. F. – NAJAFI, B. – AGHBASHLO, M. – KHOUNANI, Z. – TABATABAEI, M. 2021. Performance and emission analysis of a dual-fuel engine operating on high natural gas substitution rates ignited by aqueous carbon nanoparticles-laden diesel/biodiesel emulsions. In Fuel, vol. 294, p. 120246. Search in Google Scholar

BARANESCU, R. – CHELLEN, B. 1999. Diesel Engine Reference Book. Warrendale, Pennsylvania : Society of Automotive Engineers, 713 pp. ISBN 0750621761. Search in Google Scholar

BARI, S. 2013. Diesel Engine: Combustion, Emissions and Condition Monitoring. London : IntechOpen, 282 pp. ISBN 9789535111207. Search in Google Scholar

BORA, B. J. – SAHA, U. K. 2016. Experimental evaluation of a rice bran biodiesel–biogas run dual fuel diesel engine at varying compression ratios. In Renewable Energy, vol. 87, no. Part 1, pp. 782–790. Search in Google Scholar

CHANG, Y.-C. – LEE, W.-J. – LIN, S.-L. – WANG, L.-C. 2013. Green energy: water-containing acetone-butanol-ethanol diesel blends fueled in diesel engines. In Applied Energy, vol. 109, pp. 182–191. Search in Google Scholar

CHOI, B. – JIANG, X. – KIM, Y. K. – JUNG, G. – LEE, C. –CHOI, I. – SONG, C. S. 2015. Effect of diesel fuel blend with n-butanol on the emission of a turbocharged common rail direct injection diesel engine. In Applied Energy, vol. 146, pp. 20–28. Search in Google Scholar

GHAZALI, W. N. M. – MAMAT, R. – MASJUKI, H. H. – NAJAFI, G. J. R. 2015. Effects of biodiesel from different feedstocks on engine performance and emissions. In Renewable and Sustainable Energy Reviews, vol. 51, pp. 585–602. Search in Google Scholar

HAPPONEN, M. – HEIKKILA, J. – AAKKO-SAKSA, P. – MURTONEN, T. – LEHTO, K. – ROSTEDT, A. – SARJOVAARA, T. – LARMI, M. – KESKINEN, J. – VIRTANEN, A. 2013. Diesel exhaust emissions and particle hygroscopicity with HVO fuel-oxygenate blend. In Fuel, vol. 103, pp. 380–386. Search in Google Scholar

HARDING, K. G. 2011. An introduction to life cycle assessment (LCA). In Chemical Technology, pp. 22–25. Search in Google Scholar

HAUSCHILD, M. – BARLAZ, M. 2010. LCA in Waste Management: Introduction to Principle and Method. In CHRISTENSEN, T. H. Solid Waste Technology & Management, vol. 1 & 2. Hoboken, New Jersey : Blackwell Publishing Ltd., 1056 pp. ISBN 1405175176. Search in Google Scholar

HOSEINI, S. – NAJAFI, G. – GHOBADIAN, B. – EBADI, M. – MAMAT, R. – YUSAF, T. J. R. E. 2016. Performance and emission characteristics of a CI engine using graphene oxide (GO) nano-particles additives in biodiesel–diesel blends. In Renewable Energy, vol. 145, pp. 458–465. Search in Google Scholar

JABRAEILI, M. – POURDARBANI, R. – NAJAFI, B. – NEMATOLLAHZADEH, A. 2021. Modelling the effects of Al₂O₃–SiO₂ nanocomposite additive in biodiesel–diesel fuel on diesel engine performance using hybrid ANN–ABC. In Acta Technologica Agriculturae, vol. 24, no. 1, pp. 20–26. Search in Google Scholar

KHALIFE, E. – TABATABAEI, M. – NAJAFI, B. – MIRSALIM, S. – GHAREHGHANI, A. – MOHAMMADI, P. – AGHBASHLO, M. – GHAFFARI, A. – KHOUNANI, Z. – ROODBAR SHOJAEI, T. – AMRAN MOHD SALLEH, M. 2017. A novel emulsion fuel containing aqueous nano cerium oxide additive in diesel–biodiesel blends to improve diesel engines performance and reduce exhaust emissions: Part I – experimental analysis. In Fuel, vol. 207, pp. 741–750.10.1016/j.fuel.2017.06.033 Search in Google Scholar

KLINGLMAIR, M. – SALA, S. – BRANDAO, M. 2013. Assessing resource depletion in LCA: A review of methods and methodological issues. In The International Journal of Life Cycle Assessment, vol. 19, no. 2, pp. 156–167. Search in Google Scholar

KUMAR, C. – BAFNA, M. – NAYYAR, A. – PARKASH, V. – GOYAL, N. J. I. 2014. Experimental investigation of the performance of VCR diesel engine fuelled by NM–diesel blend. In International Journal of Research in Engineering and Technology, vol. 4, pp. 444–450. Search in Google Scholar

LA ROSA, A. – BANATAO, D. – PASTINE, S. – LATTERRI, A. – CICALA, G. 2016. Recycling treatment of carbon fibre/epoxy composites: Materials recovery and characterization and environmental impacts through life cycle assessment. In Composites Part B: Engineering, vol. 104, pp. 17–25. Search in Google Scholar

LILLY, L. C. R. 1984. Diesel Engine Reference Book. London, Boston : Butterworths, 720 pp. ISBN 9780408004435. Search in Google Scholar

LIU, H. – HUANG, Y. – YUAN, H. – YIN, X. – WU, C. J. R. 2018. Life cycle assessment of biofuels in China: Status and challenges. In Renewable and Sustainable Energy Reviews, vol. 97, pp. 301–322. Search in Google Scholar

MOLLENHAUER, K. – TSCHOKE, H. 2010. Handbook of Diesel Engines. London, New York : Springer Heidelberg Dordrecht Press, 1483 pp. ISBN 9783540890829. Search in Google Scholar

MYERS, R. H. – MONTGOMERY, D. C. – ANDERSON-COOK, C. M. 1995. Response Surface Methodology: Process and Product Optimization Using Designed Experiments. 3^rd ed., New York : Wiley Press, 704 pp. ISBN 0470174463. Search in Google Scholar

NAJAFI, B. 2011. Artificial neural networks used for the prediction of the diesel engine performance and pollution of waste cooking oil biodiesel. In Modares Mechanical Engineering, vol. 11, no. 4, pp. 11–20. Search in Google Scholar

OGUNKUNLE, O. – AHMED, N. 2019. A review of global current scenario of biodiesel adoption and combustion in vehicular diesel engines. In Energy Reports, vol. 5, pp. 1560–1579. Search in Google Scholar

PATIL, A. R. – TAJI, S. G. 2013. Effect of oxygenated fuel additive on diesel engine performance and emission: A review. In IOSR Journal of Mechanical Civil Engineering, pp. 30–35. Search in Google Scholar

POURDARBANI, R. – AMINFAR, R. 2018. Theoretical study to determine the proper injection system for upgrading fuel system of diesel engine om357 to common rail system. In International Journal of Engineering and Technology, vol. 4, no. 7, pp. 2594–2597. Search in Google Scholar

RADHAKRISHNAN, S. – MUNUSWAMY, D. B. – DEVARAJAN, Y. – MAHALINGAM, A. J. H. – TRANSFER, M. 2019. Performance, emission and combustion study on neat biodiesel and water blends fuelled research diesel engine. In Heat and Mass Treansfer, vol. 55, no. 4, pp. 1229–1237. Search in Google Scholar

RAMAKRISHNAN, P. – KASIMANI, R. – PEER, M. S. 2018. Optimization in the performance and emission parameters of a DI diesel engine fuelled with pentanol added Calophyllum inophyllum/diesel blends using response surface methodology. In Environmental Science Pollution Research, vol. 25, no. 29, pp. 29115–29128. Search in Google Scholar

SAMIR NAJE, A. – YUVARAJAN, D. – ABED AL-RIDAH, Z. – SANDEEP, H. – NAGARAJAN, A. J. F. 2020. Ignition study of neat biodiesel in dual fueled research engine. In Fuel, vol. 281, pp. 118673. Search in Google Scholar

VAN DE HEEDE, P. – DE BELIE, N. 2012. Environmental impact and life cycle assessment (LCA) of traditional and ‘green‘ concretes: Literature review and theoretical calculations. In Cement and Concrete Composites, vol. 34, pp. 431–442. Search in Google Scholar

VELLAIYAN, S. – SUBBIAH, A. – CHOCKALINGAM, P. J. E. S. 2021. Effect of Titanium dioxide nanoparticle as an additive on the working characteristics of biodiesel–water emulsion fuel blends. In Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, vol. 43, no. 9, pp. 1087–1099. Search in Google Scholar

VENKATESH, A. – POSEN, I. D. – MACLEAN, H. L. – CHU, P. L. –GRIFFIN, P. L. SAVILLE, B. A. 2019. Environmental aspects of biotechnology. In Sustainability and Life Cycle Assessment in Industrial Biotechnology, pp. 77–119. Search in Google Scholar

YILMAZ, E. S. – ARSALAN, H. M. – BIDECI, A. 2019. Environmental performance analysis of insulated composite facade panels using life cycle assessment (LCA). In Constructoin and Building Materials, vol. 202, pp. 806–813. Search in Google Scholar

YILMAZ, N. – VIGIL, F. M. 2014. Potential use of a blend of diesel, biodiesel, alcohols and vegetable oil in compression ignition engines. In Fuel, vol. 124, pp. 168–172. Search in Google Scholar