ANALYSIS OF LUBRICANT OIL DEGRADATION AND SOUND PRESSURE LEVEL FOR CI ENGINE USING BLEND FUELS

Faheem Ahmed  Solangi; Liaquat Ali  Memon; Saleem Raza  Samo; Muhammad Ramzan  Luhur; Aqeel Ahmed Bhutto; Ali Murtaza  Ansari

doi:10.11113/jurnalteknologi.v86.19756

Authors

Faheem Ahmed Solangi Quaid-e-Awam University of Engineering, Science and Technology Nawabshah, Sindh, Pakistan https://orcid.org/0009-0000-1148-239X
Liaquat Ali Memon Quaid-e-Awam University of Engineering, Science and Technology Nawabshah, Sindh, Pakistan
Saleem Raza Samo Quaid-e-Awam University of Engineering, Science and Technology Nawabshah, Sindh, Pakistan
Muhammad Ramzan Luhur Quaid-e-Awam University of Engineering, Science and Technology Nawabshah, Sindh, Pakistan https://orcid.org/0000-0003-1365-1518
Aqeel Ahmed Bhutto Mehran UET SZAB Campus Khairpur Mirs, Sindh, Pakistan https://orcid.org/0000-0002-8850-9412
Ali Murtaza Ansari Quaid-e-Awam University of Engineering, Science and Technology Nawabshah, Sindh, Pakistan https://orcid.org/0000-0001-9271-2790

DOI:

https://doi.org/10.11113/jurnalteknologi.v86.19756

Keywords:

Diesel Engine, Emulsion Fuel, Viscosity, Wear Debris, Sound Pressure Level

Abstract

Long-term engine running has been the subject of extensive research on the deterioration of engine oil. In contrast, it is not fully clear what effect synthetic and biofuels will have. Modern engines, traditional fuels and lubricants should be used to provide a research basis for characterizing novel fuel-related phenomena in engines. This study makes an effort to characterize how lubricating engine oil behaves over the course of its service life using data on friction and wear. Every 20 hours, oil samples from the engine were obtained to evaluate its chemical makeup. On a reciprocating test rig, friction and wear measurements were taken. Kinematic viscosity, density, and wear metals such as cadmium (Cd), cobalt (Co), and lead (Pb) were measured for the lubricant oil analysis. In general, n-pentanol aids in the reduction of engine wear debris, contamination, and lubricating oil oxidation. According to the findings of this study, a D60WCO20Pe15 ternary combination can be used in a diesel engine without any alteration. The sound pressure level (SPL) increased by 7.8 dB at engine speed of 1300 RPM in the case of the DF95WCO5. However, when compared to base line, the average SPL of D60WCO20Pe15 ternary blend was 4.3 dB lower.

References

Chowdary, K., Tated, M. K., & Kotia, A. 2019. Effect of Methanol and Ethanol on lubrication oil degradation of CI engine. Journal of the Gujarat Research Society. 21(8s): Special Issue.

Akal, D., Öztuna, S., Büyükakin, M. K. 2020. A Review of Hydrogen Usage In Internal Combustion Engines (Gasoline-Lpg-diesel) from Combustion Performance Aspect. Int. J. Hydrogen Energy. 45: 35257-35268.

Forero, J. D., Ochoa, G. V., Alvarado, W. P. 2020. Study of the Piston Secondary Movement on the Tribological Performance of a Single Cylinder Low-displacement Diesel Engine. Lubricants. 8: 97.

Deheri, C., Acharya, S. K., Thatoi, D. N., Mohanty, A. P. 2020. A Review on Performance of Biogas and Hydrogen on Diesel Engine in Dual Fuel Mode. Fuel. 260: 116337.

Temizer, I., Cihan, Ö., Eskici, B. 2020. Numerical and Experimental Investigation of the Effect of Biodiesel/diesel Fuel on Combustion Characteristics in CI Engine. Fuel. 270: 117523.

Khatri, N., Khatri, K. K. 2020. Hydrogen Enrichment on Diesel Engine with Biogas in Dual Fuel Mode. Int. J. Hydrogen Energy. 45: 7128-7140.

Debbarma, S., Misra, R. D., Das, B. 2020. Performance of Graphene-added Palm Biodiesel in a Diesel Engine. Clean Technol Environ Policy. https ://doi.org/10.1007/s1009 8-019-01800-2.

Dabi, M., Saha, U. K. 2019. Application Potential of Vegetable Oils as Alternative to Dieselfuels in Compression Ignition Engines: A Review. J Energy Inst. https://doi.org/10.1016/j.joei.2019.01.003.

Wei, L., Cheng, R., Mao, H., Geng, P., Zhang, Y., You, K. 2017. Combustion Process and NOx Emissions of a Marine Auxiliary Diesel Engine Fuelled with Waste Cooking Oil Biodiesel Blends. Energy. https ://doi.org/10.1016/j.energ y.2017.12.012.

Dhanasekaran, R., Ganesan, S., Kumar, B. R., Saravanan, S. 2019. Utilization of Waste Cooking Oil in a Light-duty DI Diesel Engine for Cleaner Emissions using Bio-derived Propanol. Fuel. 235: 832-837.https://doi.org/10.1016/j.fuel.2018.08.093.

Hribernik, A., Kegl, B. 2009. Performance and Exhaust Emissions of an Indirect-injection (IDI) Diesel Engine when using Waste Cooking Oil as Fuel. Energy Fuels. 23(3): 1754-8.

Kalam, M. A., Masjuki, H. H., Jayed, M. H., Liaquat, A. M. 2011. Emission and Performance Characteristics of an Indirect Ignition Diesel Engine Fuelled with Waste Cooking Oil. Energy. 36(1): 397-402. http://dx.doi.org/10.1016/j.energy.2010.10.026.

Atmanlı, A., Yüksel, B., İleri, E. 2013. Experimental Investigation of the Effect of Diesel–cotton Oil–n-butanol Ternary Blends on Phase Stability, Engine Performance and Exhaust Emission Parameters in a Diesel Engine. Fuel. 109: 503-11. http://dx. doi.org/10.1016/j.fuel.2013.03.012.

Sharon, H., Jai Shiva Ram, P. Jenis Fernando, K., Murali, S., Muthusamy, R. 2013. Fueling a Stationary Direct Injection Diesel Engine with Diesel-used Palm Oil–butanol blends – An Experimental Study. Energy Convers Manage. 73: 95-105. http://dx.doi. org/10.1016/j.enconman.2013.04.027.

Lujaji, F., Kristóf, L., Bereczky, A., Mbarawa, M. 2011. Experimental Investigation of Fuel Properties, Engine Performance, Combustion and Emissions of Blends Containing Croton Oil, Butanol, and Diesel on a CI Engine. Fuel. 90(2): 505-10. http://dx. doi.org/10.1016/j.fuel.2010.10.004.

Atmanli, A., İleri, E., Yüksel, B. 2014. Experimental Investigation of Engine Performance and Exhaust Emissions of a Diesel Engine Fueled with Diesel–n-butanol–vegetable Oil Blends. Energy Convers Manage. 81: 312-21. http://dx.doi.org/10.1016/j. enconman.2014.02.049.

Atmanlı, A., İleri, E., Yüksel, B. 2015. Effects of Higher Ratios of n-butanol Addition to Diesel–vegetable Oil Blends on Performance and Exhaust Emissions of a Diesel Engine. J Energy Inst. 88(3): 209-20. http://dx.doi.org/10.1016/j.joei.2014.09.008.

Atmanli, A., Ileri, E., Yuksel, B., Yilmaz, N. 2015. Extensive Analyses of Diesel–vegetable Oil–nbutanol Ternary Blends in a Diesel Engine. Appl Energy. 145: 155-62. http://dx. doi.org/10.1016/j.apenergy.2015.01.071.

Atmanli, A. 2016. Effects of a Cetane Improver on Fuel Properties and Engine Characteristics of a Diesel Engine Fueled with the Blends of Diesel, Hazelnut Oil and Higher Carbon Alcohol. Fuel. 172: 209-17. http://dx.doi.org/10.1016/j.fuel.2016.01.013

Atmanli, A. 2016. Comparative Analyses of Diesel–waste Oil Biodiesel and Propanol, nbutanol or 1-pentanol Blends in a Diesel Engine. Fuel. 176: 209-15. http://dx. doi.org/10.1016/j.fuel.2016.02.076.

Krishnamoorthy, V., Dhanasekaran, R., Rana, D., Saravanan, S., & Kumar, B. R. 2018. A Comparative Assessment of Ternary Blends of Three Bio-alcohols with Waste Cooking Oil and Diesel for Optimum Emissions and Performance in a CI Engine using Response Surface Methodology. Energy Conversion and Management. 156(September 2017): 337-357. https://doi.org/10.1016/j.enconman.2017.10.087.

van Eijck, J., Romijn, H., Balkema, A., Faaij, A. 2014. Global Experience with Jatropha Cultivation for Bioenergy: An Assessment of Socio-economic and Environmental Aspects. Renew. Sustain. Energy Rev. 32: 869-889.

Binhayeeding, N., Klomklao, S., Prasertsan, P., Sangkharak, K. 2020. Improvement of Biodiesel Production using Waste Cooking Oil and Applying Single and Mixed Immobilised Lipases on Polyhydroxyalkanoate. Renew. Energy. 162: 1819-1827.

Milano, J., Ong, H. C., Masjuki, H. H., Silitonga, A. S., Chen, W.-H., Kusumo, F., Dharma, S., Sebayang, A. H. 2018a. Optimization of Biodiesel Production by Microwave Irradiation-assisted Transesterification for Waste Cooking Oil- Calophyllum Inophyllum Oil Via Response Surface Methodology. Energy Convers. Manage. 158: 400-415.

Celik, I., Aydin, O. 2011. Effects of B100 Biodiesel on Injector and Pump Piston. Tribol Trans. 54: 424-31.

Sudan Reddy Dandu, M., & Nanthagopal, K. 2021. Clean Karanja Methyl Ester Compatibility Study on Long Term Tribological Behavior of a Compression Ignition Engine. Fuel. 291(January):120148.

Pandey, R. K., Rehman, A., & Sarviya, R. M. 2012. Impact of alternative Fuel Properties on fuel Spray Behavior and Atomization. Renewable and Sustainable Energy Reviews. 16(3): 1762-1778.

Russell, M. F. 1982. Diesel Engine Noise: Control at Source (No. 820238). SAE Technical Paper.

Rakopoulos, C. D., Dimaratos, A. M., Giakoumis, E. G. 2011. Study of turbocharged Diesel Engine Operation, Pollutant Emissions and Combustion Noise Radiation during Starting with Bio-dieselor n-butanol Diesel Fuel Blends. Applied Energy. 88: 3905-3916.

Nagy, A. L., Knaup, J. and Zsoldos, I. 2019. Investigation of Used Engine Oil Lubricating Performance through Oil Analysis and Friction and Wear Measurements. Acta Technica Jaurinensis. 12(3): 237-251.

Bennett, M., Volckens, J., Stanglmaier, R., McNichol, A. P., Ellenson, W. D., & Lewis, C. W. 2008. Biodiesel Effects on Particulate Radiocarbon (14C) Emissions from a Diesel Engine. Journal of Aerosol Science. 39(8): 667-678.

P. R. Wander, C. R. Altafini, A. L. Colombo, S. C. Perera. 2011. Durability Studies of Mono-cylinder Compression Ignition Engines Operating with Diesel, Soy and Castor Oil Methyl Esters. Energy. 36(6): 3917-3923. Doi: 10.1016/j.energy.2010.10.037

Haik, Y., Selim, M. Y. E., &Abdulrehman, T. 2011. Combustion of Algae Oil Methyl Ester in an Indirect Injection Diesel Engine. Energy. 36(3): 1827-1835.

Maleque, M. A., Masjuki, H. H., & Haseeb, A. S. M. A. 2000. Effect of Mechanical Factors on Tribological Properties of Palm Oil Methyl Ester Blended Lubricant. Wear. 239(1): 117-125.

Rakopoulos, C. D., Dimaratos, A. M., Giakoumis, E. G., &Rakopoulos, D. C. 2011. Study of Turbocharged Diesel Engine Operation, Pollutant Emissions and Combustion Noise Radiation during Starting with Bio-diesel or n-butanol Diesel Fuel Blends. Applied Energy. 88(11): 3905-3916.

Sudan Reddy Dandu, M., & Nanthagopal, K. 2021. Clean Karanja Methyl Ester Compatibility Study on Long Term Tribological Behavior of a Compression Ignition Engine. Fuel. 291(January): 120148. https://doi.org/10.1016/j.fuel.2021.120148

Kalam, M. A., Masjuki, H. H., Varman, V., & Liaquat, A. M. 2011a. Friction and Wear Characteristics of Waste Vegetable Oil Contaminated Lubricants. International Journal of Mechanical and Materials Engineering (IJMME). 6(3): 431-436.

Agarwal, A. K., & Dhar, A. 2010. Karanja Oil Utilization in a Direct-injection Engine by Preheating. Part 2: Experimental Investigations of Engine Durability and lubricating Oil Properties. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering. 224: 85-97.

Li, X., Guan, C., Yang, K., Cheung, C. S., Huang, Z. 2019. Impact of Lower and Higher Alcohol Additions to Diesel on the Combustion and Emissions of a Direct-injection Diesel Engine. Environ. Sci. Pollut. Res. 26: 2100-21012.

Sudan Reddy Dandu, M., & Nanthagopal, K. 2021. Clean Karanja Methyl Ester Compatibility Study on Long Term Tribological Behavior of a compression Ignition Engine. Fuel. 291(January): 120148.

ANALYSIS OF LUBRICANT OIL DEGRADATION AND SOUND PRESSURE LEVEL FOR CI ENGINE USING BLEND FUELS

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