STUDY OF THE MAIN PHYSICAL AND CHEMICAL PARAMETERS OF FUEL MIXTURES OF DIESEL FUEL AND SOYBEAN OIL

Authors

  • V. M. Melnyk ІФНТУНГ, вул. Карпатська,15, м. Івано-Франківськ, Україна
  • M. M. Hnyp ІФНТУНГ, вул. Карпатська,15, м. Івано-Франківськ, Україна

DOI:

https://doi.org/10.31471/1993-9868-2024-1(41)-118-132

Keywords:

internal combustion engine, alternative fuel, soybean oil, biodiesel, economy, mixing, physical and chemical properties, application.

Abstract

Currently, alternative fuels are experiencing a steady increase in production volumes. Europe and the world are introducing increasingly stringent environmental standards (Euro 6, starting in 2025, Euro 7), which impose requirements on cars and motor fuels that improve their environmental safety. However, most alternative fuels cannot be considered as ready-to-use motor fuels by themselves. This is due to the fact that the operational and environmental properties of most alternative fuels do not match those of commercial fuels. There are two main ways to solve this problem: 1) improving the properties of alternative fuels by refining and purifying them; 2) use of mixtures of alternative fuels with commercial fuels in certain proportions that will not harm either the engine or the environment. To improve the operational and environmental properties of commercial fuels and the industrial scale of production of alternative blended biodiesel fuels from soybean oil, we have studied the main physicochemical and operational parameters of the resulting fuel blends. According to the results of the obtained studies, the addition of soybean oil to diesel fuels in the amount of up to 60 % by volume provides an increase in its cetane number up to 11%, improves viscosity and temperature properties, and makes it possible to use such mixtures in diesel engines without changing the design of the power supply system and fuel control equipment, which characterizes soybean oil as a promising alternative fuel for internal combustion engines.

 

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References

Melnyk V. M., Voitsekhivska T. Y., Sumer A. R. Doslidzhennia osnovnykh tekhniko-ekspluatatsiinykh kharakterystyk alternatyvnykh vydiv palyva dlia dyzelnykh DVZ. Naukovi pratsi VNTU. 2018. No 2. P. 1-13. [in Ukrainian]

Yakovlieva A. V., Boichenko S. V., Hudz A. V., Zubenko S. O. Fizyko-khimichni vlastyvosti biodyzelnykh palyv na osnovi etylovykh esteriv ryzhiievoi olii. Kataliz ta naftokhimiia. 2020. No 29. P. 24-30. [in Ukrainian]

Lievtierov A. M., Savytskyi V. D. Pokrashchennia ekolohichnykh kharakterystyk dyzelia, shcho pratsiuie na biodyzelnykh palyvnykh kompozytsiiakh. Avtomobilnyi transport. 2015. No 36. P. 110-117. [in Ukrainian]

Zhurenko Yu. I., Yaropud V. M., Babyn I. A. Biodyzel – alternatyvna zamina dyzelnoho palyva. Zbirnyk naukovykh prats Vinnytskoho natsionalnoho ahrarnoho universytetu. 2012. No 10 (58). P. 44-51. [in Ukrainian]

Korpach A.O., Levkivskyi O.O. Doslidzhennia vplyvu fizyko-khimichnykh vlastyvostei biodyzelnoho palyva na palyvnu ekonomichnist, enerhetychni ta ekolohichni pokaznyky avtomobilnoho dyzelia. Visnyk ZhDTU. 2016. No 2 (77). P. 115-121. [in Ukrainian]

Kryshtopa S., Kryshtopa L., Melnyk V., Prunko I., Demianchuk Y. Experimental research on diesel engine working on a mixture of diesel fuel and fusel oils. Transport Problems. 2017. No 12 (2). Р. 53–63.

Tang Zhang-Chun, Zhenzhou Lu, Zhiwen Liu, Ningcong Xiao. Uncertainty analysis and global sensitivity analysis of techno-economic assessments for biodiesel production. Bioresource Technology. 2015. Vol. 175. P. 502–508.

Gubicza Krisztina, Nieves Ismael U., Sagues William J., Barta Zsolt, Shanmugam K.T., Ingram, Lonnie O. Techno-economic analysis of ethanol production from sugar can ebagasse using a Lique faction plus Simultaneous Saccharification and co-Fermentation process. Bioresource Technology. 2015. Vol. 208. P. 42–48.

Melnyk V. M., Liakh M. M., Synoverskyi M. M. Doslidzhennia parametriv sumisho- i teploutvorennia dyzelia u protsesi vykorystannia alternatyvnykh palyv. Naftohazova enerhetyka. 2020. No 1 (33). P. 109-123. [in Ukrainian]

Lievtierov A.M., Avramenko A.N., Savytskyi V.D. Teoretychni doslidzhennia robo-choho tsyklu biodyzelnoho dvyhuna. Avtomobilnyi transport. 2016. No 38. P. 75-82. [in Ukrainian]

Kirubakaran M., Selvan V.A.M. A com-prehensive review of lowcost biodiesel production from waste chickenfat. Renewable and sustainable energy reviews 2018. Vol. 82. P. 390-401.

Vonortas A., Papayannakos N. Comparative analysis of biodiesel versus green diesel. Wiley Interdisciplinary Reviews: Energy and Environment. 2014. Vol. 3(1). P. 3-23.

Verma P., Sharma M., Review of process parameters for biodiesel production from different feed stocks. Renewable and sustainable energy reviews. 2016. Vol. 62. P. 1063-71.

Alptekin E., Canakci M., Sanli H. Methylester production from chicken fat with high FFA. World Renewable Energy Congress, Sweden; 8-13 May; 2011; Linköping; Sweden. 2011. Linköping University Electronic Press.

Jansri S., et al. Kinetics of methylester production from mixed crude palm oil by using acid-alkali catalyst. Fuel processing technology. 2011. Vol. 92(8). P. 1543-8.

Latif M.A.A., et al. Nanostructure and oxidation properties investigation of engine using Jatropha biodiesel as engine fuel. MATEC Web of Conferences. 2017. EDP Sciences.

Tziourtzioumis D.N., Stamatelos A.M. Investigation of the effect of biodiesel blends on the performance of a fuel additive-assisted diesel filter system. International Journal of Engine Research. 2014. Vol. 15(4). P. 406-20.

Rouhany M., Montgomery H. Global Biodiesel Production: The State of the Art and Impact on Climate Change. Biodiesel. 2019, Springer. P. 1-14.

Mishra V.K., Goswami R. A review of production, properties and advantages of biodiesel. Biofuels. 2018. Vol. 9(2). P. 273-89.

Živković S., Veljković M. Environmental impacts the of production and use of biodiesel. Environmental Science and Pollution Research. 2018. Vol. 25(1). P. 191-9.

Giakoumis E.G. Analysis of 22 vegetable oils’ physico-chemical properties and fatty acid composition on a statistical basis, and correlation with the degree of unsaturation. Renewable energy. 2018. Vol. 126. P. 403-19.

El-Gharbawy A.S.A.A. Production of biodiesel from nonedible vegetable oil. 2016

Azizian H., Kramer J.K. A rapid method for the quantification of fatty acids in fat sand oils with emphasis on transfatty acids using Fouriertrans form near in frared spectroscopy (FT‐NIR). Lipids. 2005. Vol. 40(8). P. 855-67.

Balat M. Potential alternatives to edible oils for biodiesel production – A review of current work. Energy conversion and management. 2011. Vol. 52(2). P. 1479-92.

Gui M.M., K. Lee, Bhatia S. Feasibility of edible oilvs. non-edible oilvs. Waste edible oil as biodiesel feedstock. Energy. 2008. Vol. 33(11). P. 1646-53.

Rincón L., Jaramillo J., Cardona C. Comparison of feedstocks and technologies for biodiesel production: An environmental and techno-economic evaluation. Renewable Energy. 2014. Vol. 69. P. 479-87.

Ambat I., Srivastava V., Sillanpää M., Recent advancement in biodiesel production methodologies using various feedstock: A review. Renewable and sustainable energy reviews. 2018. Vol. 90. P. 356-69.

Demirbas A. Comparison of trans esterification methods for production of biodiesel from vegetable oils and fats. Energy conversion and management. 2008. Vol. 49(1). P. 125-30.

Leung D.Y., Wu X., Leung M. A review on biodiesel production using catalyzed transes terification. Applied energy. 2010. Vol. 87(4). P. 1083-95.

Likozar B., Levec J. Transes terification of canola, palm, peanut, soy bean and sun flower oil with methanol, ethanol, isopropanol, butanol and tert-butanol to biodiesel: Modelling of chemical equilibrium, reaction kinetics and mass transfer based on fatty acid composition. Applied Energy. 2014. Vol.123. P. 108-20.

Demirbas A. Biodiesel from waste cooking oil via base-catalytic and supercritical methanol trans esterification. Energy conversion and management. 2009. Vol. 50(4). P. 923-7.

Elgharbawy A.S.A. A cost analysis for biodiesel production from waste cooking oil plant in Egypt. International Journal of Smart Grid-ij Smart Grid. 2017. Vol. 1(1). P. 16-25.

Elgharbawy A.S., et al. Glycerolysis treatment to enhance biodiesel production from low-quality feedstocks. Fuel. 2021. Vol. 284. P. 118970.

Ramadhas A.S., Jayaraj S., Muraleedharan C. Biodiesel production from high FFA rubber seed oil. Fuel. 2005. Vol. 84(4). P. 335-40.

Van Gerpen J. Biodiesel processing and production. Fuel processing technology. 2005. Vol. 86(10). P. 1097-107.

Atadashi I., et al. Production of biodiesel using high free fatty acid feedstocks. Renewable and sustainable energy reviews. 2012. Vol. 16(5). P. 3275-85.

Knothe G., Van Gerpen J.H., Krahl J. The biodiesel handbook. AOCS press Champaign, IL. 2005. Vol. 1.

Anderson E., et al. Glycerin esterification of scum derived free fatty acids for biodiesel production. Bioresource technology. 2016. Vol. 200. P. 153-60.

Tan H., Aziz A.A., Aroua M. Glycerol production and its applications as a raw material: A review. Renewable and sustainable energy reviews. 2013. Vol. 27. P. 118-27.

Kombe G.G., et al., Pre-treatment of high free fatty acids oils by chemical re-esterification for biodiesel production – a review. Advances in Chemical Engineering and Science. 2013.

Felizardo P., et al., Study on the glycerolysis reaction of high free fatty acid oils for use as biodiesel feedstock. Fuel Processing Technology. 2011. Vol. 92(6). P. 1225-9.

Díaz I., et al. Synthesis of MCM-41 materials functionalised with dial kylsilane groups and their catalytic activity in the esterification of glycerol with fatty acids. Applied Catalysis A: General. 2003. Vol. 242(1). P. 161-9.

Sani Y., Daud W., Abdul Aziz A. Biodiesel feedstock and production technologies: Successes, challenges and prospects. Biodiesel-Feedstocks, Production and Applications. 2012. Vol. 10. P. 52790(2012.)

Gebremariam S., Marchetti J. Economics of biodiesel production. Energy Conversion and Management. 2018. Vol. 168. P. 74-84.

Gnanaprakasam A., et al., Recent strategy of biodiesel production from waste cooking oil and process in fluencing parameters: a review. Journal of Energy, 2013.

Bhuiya M., et al., Second generation biodiesel: potential alternative to-edible oil-derived biodiesel. Energy Procedia. 2014. Vol. 61. P. 1969-72.

Pragya N., Pandey K.K., Sahoo P. A review on harvesting, oil extraction and biofuels production technologies from microalgae. Renewable and sustainable energy reviews. 2013. Vol. 24. P. 159-71.

Karmakar A., Karmakar S., Mukherjee S. Properties of various plants and animals feedstocks for biodiesel production. Bioresource technology. 2010. Vol. 101(19). P. 7201-10.

Riazi M., Chiaramonti D. Biofuels production and processing technology. 2017: CRC Press.

Sumathi S., Chai S., Mohamed A. Utilization of oil palmas a source of renewable energy in Malaysia. Renewable and sustainable energy reviews. 2008. Vol. 12(9). P. 2404-21.

Demirbas A., Importance of biodiesel as transportation fuel. Energy policy. 2007. Vol. 35(9). P. 4661-70.

Baskar G., Aiswarya R. Trends in catalytic production of biodiesel from various feedstocks. Renewable and sustainable energy reviews. 2016. Vol. 57. P. 496-504.

Demirbas A., et al. Biodiesel production from non-edible plant oils. Energy Exploration & Exploitation. 2016. Vol. 34(2). P. 290-318.

Banković-Ilić I.B., Stamenković O.S., Veljković V.B. Biodiesel production from non-edible plant oils. Renewable and sustainable energy reviews. 2012. Vol. 16(6). P. 3621-47.

Pat. 86449 S2 Ukraina, MPK B01F 3/08, B03B 5/04. Zmishuvach dlia motornykh palyv / Melnyk V. M., Kozak F. V., KlymyshynYa. D. ; zaiavnyk i patentovlasnyk Ivano-Frankiv. nats. tekhn. un-t nafty i hazu. – No a200704406 ; zaiavleno 20.04.2007. ; opubl. 27.04.2009, Biul. No 8. 3 p. : il.[in Ukrainian]

DSTU 7688:2015 “PalyvodyzelneYevro. Tekhnichniumovy”. Vydannia ofitsiine. K.: Derzh-standart Ukrainy, 2015. 9 p.[in Ukrainian]

Published

08.10.2024

How to Cite

Melnyk, V. M., & Hnyp, M. M. (2024). STUDY OF THE MAIN PHYSICAL AND CHEMICAL PARAMETERS OF FUEL MIXTURES OF DIESEL FUEL AND SOYBEAN OIL. Oil and Gas Power Engineering, (1(41), 118–132. https://doi.org/10.31471/1993-9868-2024-1(41)-118-132

Issue

Section

NEW SOLUTIONS IN MODERN EQUIPMENT AND TECHNOLOGIES

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