Research Article
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Year 2023, Volume: 7 Issue: 2, 141 - 153, 30.06.2023
https://doi.org/10.30939/ijastech..1268355

Abstract

References

  • [1] Yilmaz IT, Gumus M. Investigation of the Effect of Biogas on Combustion and Emissions of TBC Diesel Engine. Fuel. 2017;188:69-78.
  • [2] Aklouche FZ, Loubar K, Bentebbiche A, Awad S, Tazerout M. Experimental Investigation of the Equivalence Ratio Influence on Combustion, Performance and Exhaust Emissions of a Dual Fuel Diesel Engine Operating on Synthetic Biogas Fuel. Energy Convers Manag. 2017;152:291-299.
  • [3] Kalsi SS, Subramanian KA. Effect of Simulated Biogas on Performance, Combustion and Emissions Characteristics of a Bio-diesel Fueled Diesel Engine, Renew Energ. 2017;106:78-90.
  • [4] Shan X, Qian Y, Zhu L, Lu X. Effects of EGR Rate and Hy-drogen/Carbon monoxide Ratio on Combustion and Emission Characteristics of Biogas/Diesel Dual Duel Combustion Engine. Fuel. 2016;181:1050-1057.
  • [5] Tira HS. Impact of Alternative Fuels and Hydrogen-Enriched Gaseous Fuel on Combustion and Emissions in Diesel Engines. Ph.D. Dissertation, Birmingham University, UK, 2013.
  • [6] Barik D, Murugan S. Investigation on Combustion Perfor-mance and Emission Characteristics of a DI (direct injection) Diesel Engine Fueled with Biogas-Diesel in Dual Fuel Mode. Energy. 2014;72:760-771.
  • [7] Barik D, Murugan S. Experimental Investigation on the Be-haviour of a DI Diesel Engine Fueled with Raw Biogas-Diesel Dual Fuel at Different Injection Timing. J Energy Inst. 2016;89:373-388.
  • [8] Abdul Rahman K, Ramesh A. Studies on the Effects of Me-thane Fraction and Injection Strategies in a Biogas Diesel Common Rail Dual Fuel Engine. Fuel. 2019;236:147-165.
  • [9] Bora BJ, Saha UK, Chatterjee S, Veer V. Effect of Compres-sion Ratio on Performance, Combustion and Emission Characteris-tics of a Dual Fuel Diesel Engine Run on Raw Biogas. Energy Con-vers Manag. 2014;87:1000-1009.
  • [10] Yoon SH, Lee CS. Experimental Investigation on the Com-bustion and Exhaust Emission Characteristics of Biogas-Biodiesel Dual-Fuel Combustion in a CI Engine. Fuel Process Technol. 2011;92:992-1000.
  • [11] Bouguessa R, Tarabet L, Loubar K, Bilmrabet T, Tazerout M. Experimental Investigation on Biogas Enrichment with Hydrogen for Improving the Combustion in Diesel Engine Operating Under Dual Fuel Mode. Int J Hydrog Energy 2020;45(15):9052–9063.
  • [12] Talibi M, Hellier P, Ladammatos N. Combustion and Exhaust Emission Characteristics, and In-cylinder Gas Composition of Hy-drogen Enriched Biogas Mixtures in a Diesel Engine. Energy 2017;124:397–412.
  • [13] Verma S, Das LM, Kaushik SC, Tyagi SK. An Experimental Investigation of Exergetic Performance and Emission Characteris-tics of Hydrogen Supplemented Biogas-Diesel Dual Fuel Engine. Int J Hydrog Energy 2018;43(4):2452–2468.
  • [14] Ahmed SA, Zhou S, Tsegay S, Ahmad N, and Zhu Y. Effects of Hydrogen-Enriched Biogas on Combustion and Emission of a Dual-Fuel Diesel Engine. Energy Sources Part A. 2020.
  • [15] Khatri N, Khatri KK. Hydrogen Enrichment on Diesel Engine with Biogas in Dual Fuel Mode. Int J Hydrog Energy. 2020;45(11): 7128-7140.
  • [16] Sharma H, Mahla SK, Dhir A. Effect of Utilization of Hydro-gen-Rich Reformed Biogas on the Performance and Emission Characteristics of Common Rail Diesel Engine. Int J Hydrog Ener-gy. 2022;47(18):10409-10419.
  • [17] Venkadesan G, Muthusamy J. Experimental Investigation of Al2O3/8YSZ and CeO2/8YSZ Plasma Sprayed Thermal Barrier Coat-ing on Diesel Engine. Ceram. Int. 2019;45(3):3166-3176.
  • [18] Civiniz M, Hasimoglu C, Şahin F, Salman MS. Impact of Thermal Barrier Coating Application on the Performance and Emis-sions of a Turbocharged Diesel Engine. Proc Inst Mech Eng Part D-J Automob Eng. 2008;222:2447-2455.
  • [19] Wang Y, Ma T, Liu L, Yao M. Numerical Investigation of the Effect of Thermal Barrier Coating on Combustion and Emissions in a Diesel Engine. App Therm Eng. 2021;186:116497.
  • [20] MohamedMusthafa M, Sivapirakasam SP, Udayakumar M. Comparative Studies on Fly Ash Coated Low Heat Rejection Diesel Engine on Performance and Emission Characteristics Fueled by Rice Bran and Pongamia Methyl Ester and Their Blend with Diesel. Energy 2011;36:2343-2351.
  • [21] Assanis DN, Heywood JB. Development and Use of a Com-puter Simulation of the Turbo Compounded Diesel System for En-gine Performance and Component Heat Transfer Studies. SAE Technical Papers. 1986.
  • [22] Aydin S, Sayin C, Aydin H. Investigation of the Usability of Biodiesel Obtained from Residual Frying Oil in a Diesel Engine with Thermal Barrier Coating. Appl Therm Eng. 2015;80:212-219.
  • [23] Hazar H, Ozturk U. The Effects of Al2O3-TiO2 Coating in a Diesel Engine on Performance and Emission of Corn Oil Methyl Ester. Renew Energ. 2010;35(10):2211-2216.
  • [24] Vedharaj S, Vallinayagam R. Yang WM, Chou SK, Chua KJE, Lee PS. Experimental and Finite Element Analysis of a Coated Diesel Engine Fueled by Cashew Nut Shell Liquid Biodiesel. Exp Therm Fluid Sci. 2014;53:259-268.
  • [25] Jagtap SP, Pawar AN, Lahane S. Improving the usability of biodiesel blend in low heat rejection diesel engine through combus-tion, performance and emission analysis. Renew Energ. 2020;155:628-644.
  • [26] Caputo S, Millo F, Boccardo G, Piano A, Cifali G, Resce FC. Numerical and Experimental Investigation of a Piston Thermal Bar-rier Coating for an Automotive Diesel Engine Application. App Therm Eng. 2019;162:114233.
  • [27] Paparao J, Pandey KK, Murugan S. Experimental studies on the effect of TBC piston in a dual-fueled diesel engine. Fuel 2021;306:121700.
  • [28] Paparao J, Bhopatrao S, Murugan S, Kuti OA. Optimization of a low heat rejection engine run on oxy-hydrogen gas with a bio-diesel-diesel blend. Fuel Process Technol. 2023;241:107625.
  • [29] Checkel MD, Dale JD. Computerized knock detection from engine pressure records. SAE Technical Papers. 1986.
  • [30] Shere A, Subramanian KA. Experimental Investigation on Effects of Fuel Injection Timings on Dimethyl Ether (DME) Energy Share Improvement and Emission Reduction in a Dual-Fuel CRDI Compression Ignition Engine. Int J Automot Sci Technol. 2022;6(2):98-112.
  • [31] Aydın S, Sayin C. Impact Of Thermal Barrier Coating Appli-cation on the Combustion, Performance and Emissions of a Diesel Engine Fuelled With Waste Cooking Oil Biodiesel-Diesel Blends. Fuel 2012;136:334-340.
  • [32] Vural E, Ozel S, Ozer S. Coating Diesel Engine with New Generation Ceramic Material to Improve Combustion and Perfor-mance. Therm Sci. 2021;25(1):101-110.
  • [33] Şanlı A. Experimental Study of Combustion and Cyclic Var-iations in a CRDI Engine Fueled with Heptanol/iso-propanol/butanol and Diesel Blends. Energy 2023;269:126800.
  • [34] Lounici MS, Loubar K, Tarabet L, Balistrou M, Niculescu DC, Tazerout M. Towards Improvement of Natural Gas-diesel Dual Fuel Mode: An Experimental Investigation on Performance and Exhaust Emissions . Energy 2014;64:200-211.
  • [35] Vishnoi PK, Gautam PS, Gupta VK. The impact on Combus-tion Knock in CI Engine Fueled with Methanol-Diesel-n-pentanol Ternary Blends. Mater Today: Proc.2022;52:1062-1067.
  • [36] Dernotte J, Dec J, Chunsheng J. Investigation of the Sources of Combustion Noise in HCCI Engines. SAE Technical Papers. 2014.
  • [37] Zhen X, Wang Y, Xu S, Zhu Y, Tao C, Xu T, Song M. The Engine Knocking Analysis – An Overview. Appl. Energy 2012;92:628-636.
  • [38] Numerical Study on Knock Characteristics and Mechanism of a Heavy Duty Natural Gas/diesel RCCI Engine. Int J Hydrog Ener-gy 2022;47(89):37072-37089.
  • [39] Erdoğan S, Balki MK, Sayin C. The Effect on the Knock In-tensity of High Viscosity Biodiesel Use in a DI Diesel Engine. Fuel 2019;253:1162-1167.
  • [40] Okçu M, Varol Y, Altun Ş, Fırat M. Effects of Isopropanol-Butanol-Ethanol (IBE) on Combustion Characteristics of a RCCI engine fuelled by Biodiesel Fuel. Sustain Energy Technol Assess. 2021;47:101443.
  • [41] Dhole AE, Yarasu RB, Lata DB. Investigation on the Com-bustion Duration and Ignition Delay Period of a Dual Fuel Diesel Engine with Hydrogen and Producer Gas as Secondary Fuels. App Therm Eng. 2016;107:524-532.
  • [42] Barik D, Sivalingam M. Performance and Emission Character-istics of a Biogas Fueled DI Diesel Engine. SAE Technical Papers. 2013.
  • [43] Gatts T, Li H, Liew C, Liu S, Spencer T, Wayne S, Clark N. An Experimental Investigation of H2 Emissions of a 2004 Heavy-Duty Diesel Engine Supplemented with H2. Int J Hydrog Energy. 2010;35(20):11349-11356.
  • [44] Lata DB, Misra A, Medhekar S. Effect of Hydrogen and LPG Addition on the Efficiency and Emissions of a Dual Fuel Diesel Engine. Int J Hydrog Energy. 2012;37(7):6084-6096.
  • [45] Prakash T, Edwin Geo V, Martin LJ, Nagalingam B. Effect of Ternary of Bio-Ethanol, Diesel and Castor Oil on Performance, Emission and Combustion in a CI Engine. Renew Energ. 2018;122:301-309.
  • [46] Şanlı A, Yilmaz IT, Gümüş M. Assessment of combustion and exhaust emissions in a common-rail diesel engine fuelled with methane and hydrogen/methane mixtures under different compres-sion ratio. Int J Hydrog Energy 2020;45(4):3263-3283.
  • [47] Şanlı A, Yilmaz IT, Gümüş M. Experimental Evaluation of Performance and Combustion Characteristics in a Hydrogen-Methane Port Fueled Diesel Engine at Different Compression Rati-os. Energy Fuels 2020;34(2):2272-2283.
  • [48] Dhole AE, Yarasu RB, Lata DB, Priyam A. Effect on Perfor-mance and Emissions of a Dual Fuel Diesel Engine Using Hydro-gen and Producer Gas as Secondary Fuels. Int J Hydrog Energy. 2014;39(15):8087-8097.
  • [49] Özer S, Vural E, Özel S. Effects of Fusel Oil Use in a Ther-mal Coated Engine. Fuel. 2021;306:121716.

Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine

Year 2023, Volume: 7 Issue: 2, 141 - 153, 30.06.2023
https://doi.org/10.30939/ijastech..1268355

Abstract

In this study, performance and combustion characteristics of biogas and biogas+hydrogen mixtures were experimentally analysed and compared with baseline diesel fuel in a common-rail diesel engine with and without thermal barrier coated piston. Tests were conducted at three different loads (50 Nm, 75 Nm, and 100 Nm) and a constant speed of 1750 min-1. Engine pistons were coated with Yttria Stabilized Zirconia by atmospheric plasma spray method. Results showed that by replacing the standard pistons with the coated pistons, an increase for diesel, biogas, and hydrogen enriched biogas was respectively defined by 8.1%, 6%, and 23% in cylinder pressure, and 19.8%, 12.6%, and 25% in HRR at medium load. Similarly, there was an increase in range of 1.05-12.8% in gas temperature and 20.5-117.2% in knock intensity by the piston coating. CA10-90 was prolonged between 1-15 oCA with gaseous fuel modes and increased with the engine load. Volumetric efficiency was reduced by 0.1-4% with the gaseous fuel operations, while it was increased by using the coated piston for all fuels. Exhaust gas temperature increased with the gaseous fuels whereas showed discrepancies with the coated piston engine. Dual-fuel mode and coated pis-ton application caused brake specific energy consumption to increase significantly.

References

  • [1] Yilmaz IT, Gumus M. Investigation of the Effect of Biogas on Combustion and Emissions of TBC Diesel Engine. Fuel. 2017;188:69-78.
  • [2] Aklouche FZ, Loubar K, Bentebbiche A, Awad S, Tazerout M. Experimental Investigation of the Equivalence Ratio Influence on Combustion, Performance and Exhaust Emissions of a Dual Fuel Diesel Engine Operating on Synthetic Biogas Fuel. Energy Convers Manag. 2017;152:291-299.
  • [3] Kalsi SS, Subramanian KA. Effect of Simulated Biogas on Performance, Combustion and Emissions Characteristics of a Bio-diesel Fueled Diesel Engine, Renew Energ. 2017;106:78-90.
  • [4] Shan X, Qian Y, Zhu L, Lu X. Effects of EGR Rate and Hy-drogen/Carbon monoxide Ratio on Combustion and Emission Characteristics of Biogas/Diesel Dual Duel Combustion Engine. Fuel. 2016;181:1050-1057.
  • [5] Tira HS. Impact of Alternative Fuels and Hydrogen-Enriched Gaseous Fuel on Combustion and Emissions in Diesel Engines. Ph.D. Dissertation, Birmingham University, UK, 2013.
  • [6] Barik D, Murugan S. Investigation on Combustion Perfor-mance and Emission Characteristics of a DI (direct injection) Diesel Engine Fueled with Biogas-Diesel in Dual Fuel Mode. Energy. 2014;72:760-771.
  • [7] Barik D, Murugan S. Experimental Investigation on the Be-haviour of a DI Diesel Engine Fueled with Raw Biogas-Diesel Dual Fuel at Different Injection Timing. J Energy Inst. 2016;89:373-388.
  • [8] Abdul Rahman K, Ramesh A. Studies on the Effects of Me-thane Fraction and Injection Strategies in a Biogas Diesel Common Rail Dual Fuel Engine. Fuel. 2019;236:147-165.
  • [9] Bora BJ, Saha UK, Chatterjee S, Veer V. Effect of Compres-sion Ratio on Performance, Combustion and Emission Characteris-tics of a Dual Fuel Diesel Engine Run on Raw Biogas. Energy Con-vers Manag. 2014;87:1000-1009.
  • [10] Yoon SH, Lee CS. Experimental Investigation on the Com-bustion and Exhaust Emission Characteristics of Biogas-Biodiesel Dual-Fuel Combustion in a CI Engine. Fuel Process Technol. 2011;92:992-1000.
  • [11] Bouguessa R, Tarabet L, Loubar K, Bilmrabet T, Tazerout M. Experimental Investigation on Biogas Enrichment with Hydrogen for Improving the Combustion in Diesel Engine Operating Under Dual Fuel Mode. Int J Hydrog Energy 2020;45(15):9052–9063.
  • [12] Talibi M, Hellier P, Ladammatos N. Combustion and Exhaust Emission Characteristics, and In-cylinder Gas Composition of Hy-drogen Enriched Biogas Mixtures in a Diesel Engine. Energy 2017;124:397–412.
  • [13] Verma S, Das LM, Kaushik SC, Tyagi SK. An Experimental Investigation of Exergetic Performance and Emission Characteris-tics of Hydrogen Supplemented Biogas-Diesel Dual Fuel Engine. Int J Hydrog Energy 2018;43(4):2452–2468.
  • [14] Ahmed SA, Zhou S, Tsegay S, Ahmad N, and Zhu Y. Effects of Hydrogen-Enriched Biogas on Combustion and Emission of a Dual-Fuel Diesel Engine. Energy Sources Part A. 2020.
  • [15] Khatri N, Khatri KK. Hydrogen Enrichment on Diesel Engine with Biogas in Dual Fuel Mode. Int J Hydrog Energy. 2020;45(11): 7128-7140.
  • [16] Sharma H, Mahla SK, Dhir A. Effect of Utilization of Hydro-gen-Rich Reformed Biogas on the Performance and Emission Characteristics of Common Rail Diesel Engine. Int J Hydrog Ener-gy. 2022;47(18):10409-10419.
  • [17] Venkadesan G, Muthusamy J. Experimental Investigation of Al2O3/8YSZ and CeO2/8YSZ Plasma Sprayed Thermal Barrier Coat-ing on Diesel Engine. Ceram. Int. 2019;45(3):3166-3176.
  • [18] Civiniz M, Hasimoglu C, Şahin F, Salman MS. Impact of Thermal Barrier Coating Application on the Performance and Emis-sions of a Turbocharged Diesel Engine. Proc Inst Mech Eng Part D-J Automob Eng. 2008;222:2447-2455.
  • [19] Wang Y, Ma T, Liu L, Yao M. Numerical Investigation of the Effect of Thermal Barrier Coating on Combustion and Emissions in a Diesel Engine. App Therm Eng. 2021;186:116497.
  • [20] MohamedMusthafa M, Sivapirakasam SP, Udayakumar M. Comparative Studies on Fly Ash Coated Low Heat Rejection Diesel Engine on Performance and Emission Characteristics Fueled by Rice Bran and Pongamia Methyl Ester and Their Blend with Diesel. Energy 2011;36:2343-2351.
  • [21] Assanis DN, Heywood JB. Development and Use of a Com-puter Simulation of the Turbo Compounded Diesel System for En-gine Performance and Component Heat Transfer Studies. SAE Technical Papers. 1986.
  • [22] Aydin S, Sayin C, Aydin H. Investigation of the Usability of Biodiesel Obtained from Residual Frying Oil in a Diesel Engine with Thermal Barrier Coating. Appl Therm Eng. 2015;80:212-219.
  • [23] Hazar H, Ozturk U. The Effects of Al2O3-TiO2 Coating in a Diesel Engine on Performance and Emission of Corn Oil Methyl Ester. Renew Energ. 2010;35(10):2211-2216.
  • [24] Vedharaj S, Vallinayagam R. Yang WM, Chou SK, Chua KJE, Lee PS. Experimental and Finite Element Analysis of a Coated Diesel Engine Fueled by Cashew Nut Shell Liquid Biodiesel. Exp Therm Fluid Sci. 2014;53:259-268.
  • [25] Jagtap SP, Pawar AN, Lahane S. Improving the usability of biodiesel blend in low heat rejection diesel engine through combus-tion, performance and emission analysis. Renew Energ. 2020;155:628-644.
  • [26] Caputo S, Millo F, Boccardo G, Piano A, Cifali G, Resce FC. Numerical and Experimental Investigation of a Piston Thermal Bar-rier Coating for an Automotive Diesel Engine Application. App Therm Eng. 2019;162:114233.
  • [27] Paparao J, Pandey KK, Murugan S. Experimental studies on the effect of TBC piston in a dual-fueled diesel engine. Fuel 2021;306:121700.
  • [28] Paparao J, Bhopatrao S, Murugan S, Kuti OA. Optimization of a low heat rejection engine run on oxy-hydrogen gas with a bio-diesel-diesel blend. Fuel Process Technol. 2023;241:107625.
  • [29] Checkel MD, Dale JD. Computerized knock detection from engine pressure records. SAE Technical Papers. 1986.
  • [30] Shere A, Subramanian KA. Experimental Investigation on Effects of Fuel Injection Timings on Dimethyl Ether (DME) Energy Share Improvement and Emission Reduction in a Dual-Fuel CRDI Compression Ignition Engine. Int J Automot Sci Technol. 2022;6(2):98-112.
  • [31] Aydın S, Sayin C. Impact Of Thermal Barrier Coating Appli-cation on the Combustion, Performance and Emissions of a Diesel Engine Fuelled With Waste Cooking Oil Biodiesel-Diesel Blends. Fuel 2012;136:334-340.
  • [32] Vural E, Ozel S, Ozer S. Coating Diesel Engine with New Generation Ceramic Material to Improve Combustion and Perfor-mance. Therm Sci. 2021;25(1):101-110.
  • [33] Şanlı A. Experimental Study of Combustion and Cyclic Var-iations in a CRDI Engine Fueled with Heptanol/iso-propanol/butanol and Diesel Blends. Energy 2023;269:126800.
  • [34] Lounici MS, Loubar K, Tarabet L, Balistrou M, Niculescu DC, Tazerout M. Towards Improvement of Natural Gas-diesel Dual Fuel Mode: An Experimental Investigation on Performance and Exhaust Emissions . Energy 2014;64:200-211.
  • [35] Vishnoi PK, Gautam PS, Gupta VK. The impact on Combus-tion Knock in CI Engine Fueled with Methanol-Diesel-n-pentanol Ternary Blends. Mater Today: Proc.2022;52:1062-1067.
  • [36] Dernotte J, Dec J, Chunsheng J. Investigation of the Sources of Combustion Noise in HCCI Engines. SAE Technical Papers. 2014.
  • [37] Zhen X, Wang Y, Xu S, Zhu Y, Tao C, Xu T, Song M. The Engine Knocking Analysis – An Overview. Appl. Energy 2012;92:628-636.
  • [38] Numerical Study on Knock Characteristics and Mechanism of a Heavy Duty Natural Gas/diesel RCCI Engine. Int J Hydrog Ener-gy 2022;47(89):37072-37089.
  • [39] Erdoğan S, Balki MK, Sayin C. The Effect on the Knock In-tensity of High Viscosity Biodiesel Use in a DI Diesel Engine. Fuel 2019;253:1162-1167.
  • [40] Okçu M, Varol Y, Altun Ş, Fırat M. Effects of Isopropanol-Butanol-Ethanol (IBE) on Combustion Characteristics of a RCCI engine fuelled by Biodiesel Fuel. Sustain Energy Technol Assess. 2021;47:101443.
  • [41] Dhole AE, Yarasu RB, Lata DB. Investigation on the Com-bustion Duration and Ignition Delay Period of a Dual Fuel Diesel Engine with Hydrogen and Producer Gas as Secondary Fuels. App Therm Eng. 2016;107:524-532.
  • [42] Barik D, Sivalingam M. Performance and Emission Character-istics of a Biogas Fueled DI Diesel Engine. SAE Technical Papers. 2013.
  • [43] Gatts T, Li H, Liew C, Liu S, Spencer T, Wayne S, Clark N. An Experimental Investigation of H2 Emissions of a 2004 Heavy-Duty Diesel Engine Supplemented with H2. Int J Hydrog Energy. 2010;35(20):11349-11356.
  • [44] Lata DB, Misra A, Medhekar S. Effect of Hydrogen and LPG Addition on the Efficiency and Emissions of a Dual Fuel Diesel Engine. Int J Hydrog Energy. 2012;37(7):6084-6096.
  • [45] Prakash T, Edwin Geo V, Martin LJ, Nagalingam B. Effect of Ternary of Bio-Ethanol, Diesel and Castor Oil on Performance, Emission and Combustion in a CI Engine. Renew Energ. 2018;122:301-309.
  • [46] Şanlı A, Yilmaz IT, Gümüş M. Assessment of combustion and exhaust emissions in a common-rail diesel engine fuelled with methane and hydrogen/methane mixtures under different compres-sion ratio. Int J Hydrog Energy 2020;45(4):3263-3283.
  • [47] Şanlı A, Yilmaz IT, Gümüş M. Experimental Evaluation of Performance and Combustion Characteristics in a Hydrogen-Methane Port Fueled Diesel Engine at Different Compression Rati-os. Energy Fuels 2020;34(2):2272-2283.
  • [48] Dhole AE, Yarasu RB, Lata DB, Priyam A. Effect on Perfor-mance and Emissions of a Dual Fuel Diesel Engine Using Hydro-gen and Producer Gas as Secondary Fuels. Int J Hydrog Energy. 2014;39(15):8087-8097.
  • [49] Özer S, Vural E, Özel S. Effects of Fusel Oil Use in a Ther-mal Coated Engine. Fuel. 2021;306:121716.
There are 49 citations in total.

Details

Primary Language English
Subjects Mechanical Engineering
Journal Section Articles
Authors

Ali Şanlı 0000-0002-7965-5637

İlker Turgut Yılmaz 0000-0002-0398-7635

Metin Gümüş 0000-0002-0945-6827

Publication Date June 30, 2023
Submission Date March 20, 2023
Acceptance Date May 4, 2023
Published in Issue Year 2023 Volume: 7 Issue: 2

Cite

APA Şanlı, A., Yılmaz, İ. T., & Gümüş, M. (2023). Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine. International Journal of Automotive Science And Technology, 7(2), 141-153. https://doi.org/10.30939/ijastech..1268355
AMA Şanlı A, Yılmaz İT, Gümüş M. Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine. IJASTECH. June 2023;7(2):141-153. doi:10.30939/ijastech.1268355
Chicago Şanlı, Ali, İlker Turgut Yılmaz, and Metin Gümüş. “Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine”. International Journal of Automotive Science And Technology 7, no. 2 (June 2023): 141-53. https://doi.org/10.30939/ijastech. 1268355.
EndNote Şanlı A, Yılmaz İT, Gümüş M (June 1, 2023) Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine. International Journal of Automotive Science And Technology 7 2 141–153.
IEEE A. Şanlı, İ. T. Yılmaz, and M. Gümüş, “Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine”, IJASTECH, vol. 7, no. 2, pp. 141–153, 2023, doi: 10.30939/ijastech..1268355.
ISNAD Şanlı, Ali et al. “Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine”. International Journal of Automotive Science And Technology 7/2 (June 2023), 141-153. https://doi.org/10.30939/ijastech. 1268355.
JAMA Şanlı A, Yılmaz İT, Gümüş M. Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine. IJASTECH. 2023;7:141–153.
MLA Şanlı, Ali et al. “Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine”. International Journal of Automotive Science And Technology, vol. 7, no. 2, 2023, pp. 141-53, doi:10.30939/ijastech. 1268355.
Vancouver Şanlı A, Yılmaz İT, Gümüş M. Effects of Thermal Barrier Coated Piston on Performance and Combustion Characteristics in Dual-Fuel Common-Rail Diesel Engine. IJASTECH. 2023;7(2):141-53.


International Journal of Automotive Science and Technology (IJASTECH) is published by Society of Automotive Engineers Turkey

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