Advanced search
Publication Cover
Biofuels Volume 14, 2023 - Issue 9
Submit an article Journal homepage
213
Views
1
CrossRef citations to date
0
Altmetric
Research Article

Research on the usability of various oxygenated fuel additives in a spark-ignition engine considering thermodynamic and economic analyses

Murat Kadir Yesilyurta Department of Mechanical Engineering, Faculty of Engineering–Architecture, Yozgat Bozok University, Yozgat, TurkeyCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0003-0870-7564
ORCID Icon,
Battal Doganb Department of Energy Systems Engineering, Faculty of Technology, Gazi University, Ankara, Turkey
&
Abdülvahap Cakmakc Department of Motor Vehicles and Transportation Technologies, Kavak Vocational School, Samsun University, Samsun, Turkey
Pages 933-949 | Received 20 Dec 2022, Accepted 11 Mar 2023, Published online: 31 Mar 2023

References

  • Khan SAR, Zhang Y, Kumar A, et al. Measuring the impact of renewable energy, public health expenditure, logistics, and environmental performance on sustainable economic growth. Sustain Dev. 2020;28(4):833–843.
  • Zaman K, Moemen MA. Energy consumption, carbon dioxide emissions and economic development: evaluating alternative and plausible environmental hypothesis for sustainable growth. Renew Sustain Energy Rev. 2017;74:1119–1130.
  • Pao H-T, Tsai C-M. CO2 emissions, energy consumption and economic growth in BRIC countries. Energy Policy. 2010;38(12):7850–7860.
  • Hanif I. Impact of fossil fuels energy consumption, energy policies, and urban sprawl on carbon emissions in east asia and the pacific: a panel investigation. Energy Strateg Rev. 2018;21:16–24.
  • Reitz RD, Ogawa H, Payri R, et al. IJER editorial: the future of the internal combustion engine. Int J Engine Res. 2020;21(1):3–10.
  • Kalghatgi G. Is it really the end of internal combustion engines and petroleum in transport? Appl Energy. 2018;225:965–974.
  • Chehrmonavari H, Kakaee A, Hosseini SE, et al. Hybridizing solid oxide fuel cells with internal combustion engines for power and propulsion systems: a review. Renew Sustain Energy Rev. 2023;171:112982.
  • García A, Monsalve-Serrano J, Martínez-Boggio S, et al. Potential of hybrid powertrains in a variable compression ratio downsized turbocharged VVA spark ignition engine. Energy. 2020;195:117039.
  • Boretti A. Advantages and disadvantages of diesel single and dual-fuel engines. Front Mech Eng. 2019;5:64.
  • Cerri T, D’Errico G, Onorati A. Experimental investigations on high octane number gasoline formulations for internal combustion engines. Fuel. 2013;111:305–315.
  • Walsh MP,. The global experience with lead in gasoline and the lessons we should apply to the use of MMT. Am. J. Ind. Med. 2007;50(11):853–860.
  • Anderson ST, Elzinga A. A ban on one is a boon for the other: strict gasoline content rules and implicit ethanol blending mandates. J Environ Econ Manage. 2014;67(3):258–273.
  • Çakmak A, Özcan H. Benzin için oksijenli yakıt katkıları. Politek Derg. 2018;21:831–840.
  • Nadim F, Zack P, Hoag GE, et al. United States experience with gasoline additives. Energy Policy. 2001;29(1):1–5.
  • Patil AR, Yerrawar RN, Nigade SA, et al. Literature review on need of composite additives for SI engine. Int J Res Dev Technol. 2014;2:8–12.
  • Topgül T. The effects of MTBE blends on engine performance and exhaust emissions in a spark ignition engine. Fuel Process Technol. 2015;138:483–489.
  • Yuan W, Frey HC, Wei T, et al. Comparison of real-world vehicle fuel use and tailpipe emissions for gasoline-ethanol fuel blends. Fuel. 2019;249:352–364.
  • Zhao Z, Yu X, Huang Y, et al. Experimental study on combustion and emission of an SI engine with ethanol/gasoline combined injection and EGR. J Clean Prod. 2022;331:129903.
  • Li X, Zhen X, Wang Y, et al. The knock study of high compression ratio SI engine fueled with methanol in combination with different EGR rates. Fuel. 2019;257:116098.
  • Hu T, Wei Y, Liu S, et al. Improvement of Spark-Ignition (SI) engine combustion and emission during cold start, fueled with methanol/gasoline blends. Energy Fuels. 2007;21(1):171–175.
  • Gong C, Yi L, Zhang Z, et al. Assessment of ultra-lean burn characteristics for a stratified-charge direct-injection spark-ignition methanol engine under different high compression ratios. Appl Energy. 2020;261:114478.
  • Tian Z, Zhen X, Wang Y, et al. Comparative study on combustion and emission characteristics of methanol, ethanol and butanol fuel in TISI engine. Fuel. 2020;259:116199.
  • Veza I, Said MFM, Latiff ZA. Progress of acetone-butanol-ethanol (ABE) as biofuel in gasoline and diesel engine: a review. Fuel Process Technol. 2019;196:106179.
  • Hussain A, Usman SK, Umer M, et al. A novel analysis of n-butanol–gasoline blends impact on spark ignition engine characteristics and lubricant oil degradation. Energy Sources, Part A Recover Util Environ Eff. 2022;1–15.
  • Li Y, Meng L, Nithyanandan K, et al. Experimental investigation of a spark ignition engine fueled with acetone-butanol-ethanol and gasoline blends. Energy. 2017;121:43–54.
  • Sales A, Felipe L de O, Bicas JL. Production, properties, and applications of α-Terpineol. Food Bioprocess Technol. 2020;13(8):1261–1279.
  • Vallinayagam R, Vedharaj S, Roberts WL, et al. Performance and emissions of gasoline blended with terpineol as an octane booster. Renew Energy. 2017;101:1087–1093.
  • Sivasubramanian H. Effect of ignition delay (ID) on performance, emission and combustion characteristics of 2-Methyl Furan-Unleaded gasoline blends in a MPFI SI engine. Alexandria Eng J. 2018;57(1):499–507.
  • Çakmak A, Bilgin A. Exergy and energy analysis with economic aspects of a diesel engine running on biodiesel-diesel fuel blends. IJEX. 2017;24(2/3/4):151.
  • Kopac M, Kokturk L. Determination of optimum speed of an internal combustion engine by exergy analysis. IJEX. 2005;2(1):40–54.
  • Rosen MA, Dincer I, Kanoglu M. Role of exergy in increasing efficiency and sustainability and reducing environmental impact. Energy Policy. 2008;36(1):128–137.
  • Feng H, Xiao S, Wang NZ, et al. Thermodynamic analysis of using ethanol—methanol—gasoline blends in a turbocharged, Spark-Ignition engine. J Energy Resour Technol. 2021;143(12):12090
  • Doğan B, Erol D, Yaman H, et al. The effect of ethanol-gasoline blends on performance and exhaust emissions of a spark ignition engine through exergy analysis. Appl Therm Eng. 2017;120:433–443.
  • Kiani Deh Kiani M, Rostami S, Eslami M, et al. The effect of inlet temperature and spark timing on thermo-mechanical, chemical and the total exergy of an SI engine using bioethanol-gasoline blends. Energy Convers Manag. 2018;165:344–353.
  • Çakmak A, Kapusuz M, Özcan H. Experimental research on ethyl acetate as novel oxygenated fuel in the spark-ignition (SI) engine. Energy Sources Part A Recover Util Environ Eff. 2023;45:178–193.
  • Yeşilyurt MK, Erol D, Yaman H, et al. Effects of using ethyl acetate as a surprising additive in SI engine pertaining to an environmental perspective. Int J Environ Sci Technol. 2022;19(10):9427–9456.
  • Doğan B, Yeşilyurt MK, Erol D, et al. Effects of various long-chain alcohols as alternative fuel additives on exergy and cost in a spark-ignition engine. IJEX. 2022;38(1):27–48.
  • Yesilyurt MK, Yaman H. Comprehensive investigation of using n-butanol/gasoline blends in a port-fuel injection spark-ignition engine. IJEX. 2022;37(1):1–23.
  • Ghazikhani M, Hatami M, Safari B. The effect of alcoholic fuel additives on exergy parameters and emissions in a two stroke gasoline engine. Arab J Sci Eng. 2014;39(3):2117–2125.
  • Raj R, Singh DK, Tirkey JV. Co-gasification of low-grade coal with Madhuca longifolia (Mahua) biomass and dual-fuelled mode engine performance: effect of biomass blend and engine operating condition. Energy Convers Manage. 2022;269:116150.
  • Singh DK, Tirkey JV. Process modelling and thermodynamic performance optimization of biomass air gasification fuelled with waste poultry litter pellet by integrating Aspen plus with RSM. Biomass Bioenergy. 2022;158:106370.
  • Singh DK, Tirkey JV. Performance optimization through response surface methodology of an integrated coal gasification and CI engine fuelled with diesel and low-grade coal-based producer gas. Energy. 2022;238:121982.
  • Singh DK, Tirkey JV. Modeling and multi-objective optimization of variable air gasification performance parameters using syzygium cumini biomass by integrating ASPEN plus with response surface methodology (RSM). Int J Hydrogen Energy. 2021;46(36):18816–18831.
  • Singh DK, Tirkey JV. Valorisation of hazardous medical waste using steam injected plasma gasifier: a parametric study on the modelling and multi-objective optimisation by integrating aspen plus with RSM. Environ Technol. 2022;43(27):4291–4305.
  • Singh DK, Raj R, Tirkey JV. Performance and emission analysis of triple fuelled CI engine utilizing producer gas, biodiesel and diesel: an optimization study using response surface methodology. Therm Sci Eng Progr. 2022;36:101486.
  • Mohebbi M, Reyhanian M, Hosseini V, et al. Performance and emissions of a reactivity controlled light-duty diesel engine fueled with n-butanol-diesel and gasoline. Appl Therm Eng. 2018;134:214–228.
  • Cakmak A, Kapusuz M, Ganiyev O, et al. Effects of methyl acetate as oxygenated fuel blending on performance and emissions of SI engine. Rigas Tehniskas Universitates Zinatniskie Raksti. 2018;22(1):55–68.
  • Yusuf AA, Inambao FL. Progress in alcohol-gasoline blends and their effects on the performance and emissions in SI engines under different operating conditions. Int J Ambient Energy. 2021;42(4):465–481.
  • Dabbagh HA, Ghobadi F, Ehsani MR, et al. The influence of ester additives on the properties of gasoline. Fuel. 2013;104:216–223.
  • Badawy T, Williamson J, Xu H. Laminar burning characteristics of ethyl propionate, ethyl butyrate, ethyl acetate, gasoline and ethanol fuels. Fuel. 2016;183:627–640.
  • Vallinayagam R, Vedharaj S, Naser N, et al. Terpineol as a novel octane booster for extending the knock limit of gasoline. Fuel. 2017;187:9–15.
  • Londhe H, Luo G, Park S, et al. Testing of anisole and methyl acetate as additives to diesel and biodiesel fuels in a compression ignition engine. Fuel. 2019;246:79–92.
  • Jin C, Zhang X, Geng Z, et al. Effects of various co-solvents on the solubility between blends of soybean oil with either methanol or ethanol. Fuel. 2019;244:461–471.
  • Aguado-Deblas L, Estevez R, Hidalgo-Carrillo J, et al. Outlook for direct use of sunflower and castor oils as biofuels in compression ignition diesel engines, being part of diesel/ethyl acetate/straight vegetable oil triple blends. Energies. 2020;13(18):4836.
  • Mourad M, Mahmoud KJRE. Investigation into SI engine performance characteristics and emissions fuelled with ethanol/butanol-gasoline blends. Renew Energy. 2019;143:762–771.
  • Krishna SM, Salam PA, Tongroon M, et al. Performance and emission assessment of optimally blended biodiesel-diesel-ethanol in diesel engine generator. Appl Therm Eng. 2019;155:525–533.
  • McMillan ML, Halsall R. Fuel effects on combustion and emissions in a direct injection diesel engine. SAE Tech Pap. 1988;881650.
  • Silva RD, Cataluña R, De Menezes EW, et al. Effect of additives on the antiknock properties and reid vapor pressure of gasoline. Fuel. 2005;84:951–959.
  • Holman P. Experimental methods for engineers. 8th ed. New York, USA: McGraw-Hill; 2012.
  • Yeşilyurt MK. The examination of a Compression-Ignition engine powered by peanut oil biodiesel and diesel fuel in terms of energetic and exergetic performance parameters. Fuel. 2020;278:118319.
  • Yildiz I, Caliskan H, Mori K. Energy, exergy and environmental assessments of biodiesel and diesel fuels for an internal combustion engine using silicon carbide particulate filter. J Therm Anal Calorim. 2021b;145(3):739–750.
  • Yaqoob H, Teoh YH, Sher F, et al. Energy, exergy, sustainability and economic analysis of waste tire pyrolysis oil blends with different nanoparticle additives in spark ignition engine. Energy. 2022;251:123697.
  • Yesilyurt MK, Arslan M. Analysis of the fuel injection pressure effects on energy and exergy efficiencies of a diesel engine operating with biodiesel. Biofuels. 2019;10(5):643–655.
  • Karagoz M, Uysal C, Agbulut U, et al. Energy, exergy, economic and sustainability assessments of a compression ignition diesel engine fueled with tire pyrolytic oil − diesel blends. J Cleaner Prod. 2020;264:121724.
  • Kotas TJ. 2012. The exergy method of thermal plant analysis. Butterworths, London: Paragon Publishing.
  • Odibi C, Babaie M, Zare A, et al. Exergy analysis of a diesel engine with waste cooking biodiesel and triacetin. Energy Convers Manage. 2019;198:111912.
  • Karthickeyan V, Thiyagarajan S, Ashok B, et al. Experimental investigation of pomegranate oil methyl ester in ceramic coated engine at different operating condition in direct injection diesel engine with energy and exergy analysis. Energy Convers Manage. 2020;205:112334.
  • Nabi MN, Rasul MG, Anwar M, et al. Energy, exergy, performance, emission and combustion characteristics of diesel engine using new series of non-edible biodiesels. Renew Energy. 2019;140:647–657.
  • Dogan B, Cakmak A, Yesilyurt MK, et al. Investigation on 1-heptanol as an oxygenated additive with diesel fuel for compression-ignition engine applications: an approach in terms of energy, exergy, exergoeconomic, enviroeconomic, and sustainability analyses. Fuel. 2020;275:117973.
  • Chaudhary V, Gakkhar R. Exergy based performance comparison of DI diesel engine fuelled with WCO15 and NEEM15 biodiesel. Environ Prog Sustainable Energy. 2020;39(3):e13363.
  • Nabi MN, Rasul MG, Arefin MA, et al. Investigation of major factors that cause diesel NOx formation and assessment of energy and exergy parameters using e-diesel blends. Fuel. 2021;292:120298.
  • Yao ZM, Qian ZQ, Li R, et al. Energy efficiency analysis of marine high-powered medium-speed diesel engine base on energy balance and exergy. Energy. 2019;176:991–1006.
  • Doğan B, Özer S, Erol D. Exergy, exergoeconomic, and exergoenviroeconomic evaluations of the use of diesel/fuel oil blends in compression ignition engines. Sustainable Energy Technol Assess. 2022;53:102475.
  • Cavalcanti EJ, Carvalho M, Ochoa AA. Exergoeconomic and exergoenvironmental comparison of diesel-biodiesel blends in a direct injection engine at variable loads. Energy Convers Manage. 2019;183:450–461.
  • Aghbashlo M, Tabatabaei M, Khalife E, et al. Exergoeconomic analysis of a DI diesel engine fueled with diesel/biodiesel (B5) emulsions containing aqueous nano cerium oxide. Energy. 2018;149:967–978.
  • Aghbashlo M, Rastegari H, Ghaziaskar HS, et al. Exergy, economic, and environmental assessment of ethanol dehydration to diesel fuel additive diethyl ether. Fuel. 2022;308:121918.
  • Ağbulut Ü, Uysal C, Cavalcanti EJ, et al. Exergy, exergoeconomic, life cycle, and exergoenvironmental assessments for an engine fueled by diesel–ethanol blends with aluminum oxide and titanium dioxide additive nanoparticles. Fuel. 2022;320:123861.
  • Kul BS, Ciniviz M. An evaluation based on energy and exergy analyses in SI engine fueled with waste bread bioethanol-gasoline blends. Fuel. 2021;286:119375.
  • Zapata-Mina J, Restrepo A, Romero C, et al. Exergy analysis of a diesel engine converted to spark ignition operating with diesel, ethanol, and gasoline/ethanol blends. Sustainable Energy Technol Assess. 2020;42:100803.
  • Paul A, Panua R, Debroy D. An experimental study of combustion, performance, exergy and emission characteristics of a CI engine fueled by diesel-ethanol-biodiesel blends. Energy. 2017;141:839–852.
  • Rufino CH, de Lima AJ, Mattos AP, et al. Exergetic analysis of a spark ignition engine fuelled with ethanol. Energy Convers Manage. 2019;192:20–29.
  • Hoseinpour M, Sadrnia H, Tabasizadeh M, et al. Energy and exergy analyses of a diesel engine fueled with diesel, biodiesel-diesel blend and gasoline fumigation. Energy. 2017;141:2408–2420.
  • Verma S, Das LM, Kaushik SC, et al. An experimental investigation of exergetic performance and emission characteristics of hydrogen supplemented biogas-diesel dual fuel engine. Int J Hydrogen Energy. 2018;43(4):2452–2468.
  • Verma S, Das LM, Kaushik SC. Effects of varying composition of biogas on performance and emission characteristics of compression ignition engine using exergy analysis. Energy Convers Manage. 2017;138:346–359.
  • Doğan B, Erol D, Kodanlı E. The investigation of exergoeconomic, sustainability and environmental analyses in an SI engine fuelled with different ethanol-gasoline blends. IJEX. 2020;32(4):412–436.
  • Ghadikolaei MA, Wong PK, Cheung CS, et al. Why is the world not yet ready to use alternative fuel vehicles? Heliyon. 2021;7(7):e07527.
  • Aghbashlo M, Tabatabaei M, Mohammadi P, et al. Neat diesel beats waste-oriented biodiesel from the exergoeconomic and exergoenvironmental point of views. Energy Convers Manage. 2017;148:1–15.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.