In the wake of rising prices and unstable supply besides environmental issues, renewed attention has been paid to shifting away from the use of petroleum based fuels. The world’s energy demand is commencing its dependency on alternative fuels. Such alternative fuels in use today consist of bio-alcohols (such as ethanol), biomass, and natural oil/fat-derived fuels. In search for new energy sources, much attention is focused on biodiesel as a reliable and renewable resource that is to satisfy a significant part of the energy demands. The oil extracted from the dried seeds of Ricinus communis was used in the production of biodiesel under the condition of 3:1 methanol/oil molar ratio for 1hour at 65°C. The biodiesel produced was subjected to physiochemical analysis. The methyl esters produced were found to meet the ASTM standards for biodiesel. The results obtained from analysis of biodiesel from Ricinus communis include free fatty acid: 0.312%; acid value: 0.628mgKOH/g; specific gravity: 0.8937; kinematic velocity: 7.435Cst; refractive index: 1.6254; flash point: 155°C; fire point: 132°C; water content: 3.24%. Thus, the values obtained met with the ASTM standard making the sample a promising potential for biodiesel production. From the result of this work, the oil extracted from the Ricinus communis seed is a potential feedstock for the production of quality biodiesel since almost all the fuel characteristics met the ASTM standards for biodiesel.
| Published in | Journal of Biomaterials (Volume 2, Issue 2) |
| DOI | 10.11648/j.jb.20180202.11 |
| Page(s) | 24-30 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Bio-Diesel, Ricinus communis, Physiochemical Analysis, Specific Gravity, Water Content, Biofuel
| [1] | Seema, R. and Bhandari, M. (2017), Comparison of Methods of Production of Biodiesel from Jatropha Curcas. Journal of Biofuels. 8 (2): 58-80. |
| [2] | Pradeep, U. G., Balan, K. N., and Bapu, B. R. R. (2017). International Conference on ideas, Impact and Innovation in Mechanical Engineering, 5 (6): 1057-1062. |
| [3] | Vaccaro L. (2017). Biofuels and green chemistry - a common journey ahead. Biofuel Research Journal. 713-714. DOI: 10.18331/BRJ2017.4.4.2. |
| [4] | Yadessa, G. K., and Jorge, M. M. (2017). Oil extraction from plant seeds for biodiesel production. AIMS Energy Journal, 5 (2): 316-340. |
| [5] | Aisha, A. J., Abdulaziz, A., Muataz, K., Zaiton, A. M. (2017). Transesterification of croton megalocarpus oil to biodiesel over WO3 supported on silica. The chemical Engineering Journal, 316 (1); 882-892. |
| [6] | Habibullah, M., Masjuki, H. H., Kalam, M. A., Ashrafur R. S. M., Mofijur, M., Mobarak, H. M., and Ashraful, A. M. (2015). Potential of biodiesel as a renewable energy source in Bangladesh. Renewable and Sustainable Energy Reviews, 50 (1): 819-834. |
| [7] | Humphrey, I., Nsikan, I. O., and Michael A., Chendo, C. (2015). Comparative Studies on Some Edible Oils for Biodiesel Production in Nigeria. British Biotechnology Journal, 5 (2): 72-83. |
| [8] | ASTM international (2016), standard test methods for biodiesel (B 100) analysis. Annual book of standards, D 6571. ASTM international west Conshohocken, pp. 734-738. |
| [9] | Alemayehu, G., Tewodros, G., and Abile, T. (2015). A Review on Biodiesel Production as Alternative Fuel. Journal of forest products & industries, 4 (2): 80-85. |
| [10] | Eze, S. O. (2012). Physico-chemical properties of oil from some selected underutilized oil seeds available for biodiesel preparation. African Journal of Biotechnology, 11 (42): 10003-10007. |
| [11] | Mehdi, A. and Hamid, R. K. (2011), Characterization and trans-esterification Iranian bitter almond oil for biodiesel production, Applied Energy, 88 (7): 23 - 77. |
| [12] | National standard for biodiesel, (2016), Setting National fuel quality standards, Department of environment and heritage, Australia. p 25. |
| [13] | Nezehat B., Miray K., Oylum S., Ertan A. and Nebahat D. (2009), investigation of the fuel properties of biodiesel produced over an alumina based solid catalyst, Turkey journal chem.., 33: 433-442. |
| [14] | Oghenejoboh K. M. and Umukoro P. O. (2011), Comparative analysis of fuel characteristics of biodiesel produced from selected oil bearing seeds in Nigeria, European Journal of Scientific Research, 58 (2): 238-246. |
| [15] | Parthiban, K. T., et al., (2011), physicochemical characterization of seed oil from jatrophacurcasgenetic resources, Journal of Ecological and NaturalEnvironment. 3 (5): 163-167. |
| [16] | Anitha, A. and Dawn, S. S. (2010), Performance characteristics of biodiesel produced from waste groundnut oil using supported heteropolyacids, internal journal of chemical engineering and applications, 1 (3), 261-265. |
| [17] | Rachimoellah H. M., Dyah A. R., Ali Z. and Wayan I. S. (2009), production of biodiesel through transesterification of avocado seed oil using base catalyst, Journal TeknikMesin, 11 (2):85. |
| [18] | Reynolds E. R., Gary H., Robert L. M., Allen K., Albert M. H. and Carlton J. (2017), changes in diesel, Transportation Fuels Consulting Inc. Milford, pp. 21-25. |
| [19] | Shannon D. S., James M. W., Parag S. S., Claudia W, Marlen A. V. and Glen R. M. (2009), Feedstock and biodiesel characteristics Report, Renewable energy group Inc., 416 S. Avenue, pp. 11-88. |
| [20] | Singh, R. K., and Pahdi, K. S. (2009), Characterization of jatropha oil for the production of biodiesel, Natural Product Rediance. 8: 127-132. |
| [21] | Singh, S. P., and Singh, D. (2010), Biodiesel production through the use of different sources and characterization of oils and their esters as the substitute of biodiesel: A review: Renewable and Sustainable Energy Reviews. 14: 200- 216. |
| [22] | Sivaramakrishnan, K., and Ravikumar, P. (2012), Determination of cetane number of biodiesel and its influence on physical properties, ARPN Journal of Engineeringand Applied Sciences. 7: 205-211. |
| [23] | Van G. J., Shanks B., Pruszko R., Clements D. and Knothe G. (2004), Biodiesel production technology, National Renewability Energy Laboratory, 1617 Cole Boulevard, Golden, Colorado. pp. 1-41. |
| [24] | Xiaohu F., Xi W. and Feng C. (2011), Biodiesel production from crude cotton seed oil: An optimization process using response surface Methodology, The Open Fuels and Energy Science Journal, 4: 1-8. |
APA Style
Iwuozor Kingsley Ogemdi, Ayofe Isreal Ibraheem. (2018). Production of Biodiesel and its Physiochemical Properties Produced from Ricinus communis Seeds by Trans-Esterification Process. Journal of Biomaterials, 2(2), 24-30. https://doi.org/10.11648/j.jb.20180202.11
ACS Style
Iwuozor Kingsley Ogemdi; Ayofe Isreal Ibraheem. Production of Biodiesel and its Physiochemical Properties Produced from Ricinus communis Seeds by Trans-Esterification Process. J. Biomater. 2018, 2(2), 24-30. doi: 10.11648/j.jb.20180202.11
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Download@article{10.11648/j.jb.20180202.11,
author = {Iwuozor Kingsley Ogemdi and Ayofe Isreal Ibraheem},
title = {Production of Biodiesel and its Physiochemical Properties Produced from Ricinus communis Seeds by Trans-Esterification Process},
journal = {Journal of Biomaterials},
volume = {2},
number = {2},
pages = {24-30},
doi = {10.11648/j.jb.20180202.11},
url = {https://doi.org/10.11648/j.jb.20180202.11},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jb.20180202.11},
abstract = {In the wake of rising prices and unstable supply besides environmental issues, renewed attention has been paid to shifting away from the use of petroleum based fuels. The world’s energy demand is commencing its dependency on alternative fuels. Such alternative fuels in use today consist of bio-alcohols (such as ethanol), biomass, and natural oil/fat-derived fuels. In search for new energy sources, much attention is focused on biodiesel as a reliable and renewable resource that is to satisfy a significant part of the energy demands. The oil extracted from the dried seeds of Ricinus communis was used in the production of biodiesel under the condition of 3:1 methanol/oil molar ratio for 1hour at 65°C. The biodiesel produced was subjected to physiochemical analysis. The methyl esters produced were found to meet the ASTM standards for biodiesel. The results obtained from analysis of biodiesel from Ricinus communis include free fatty acid: 0.312%; acid value: 0.628mgKOH/g; specific gravity: 0.8937; kinematic velocity: 7.435Cst; refractive index: 1.6254; flash point: 155°C; fire point: 132°C; water content: 3.24%. Thus, the values obtained met with the ASTM standard making the sample a promising potential for biodiesel production. From the result of this work, the oil extracted from the Ricinus communis seed is a potential feedstock for the production of quality biodiesel since almost all the fuel characteristics met the ASTM standards for biodiesel.},
year = {2018}
}
TY - JOUR T1 - Production of Biodiesel and its Physiochemical Properties Produced from Ricinus communis Seeds by Trans-Esterification Process AU - Iwuozor Kingsley Ogemdi AU - Ayofe Isreal Ibraheem Y1 - 2018/11/27 PY - 2018 N1 - https://doi.org/10.11648/j.jb.20180202.11 DO - 10.11648/j.jb.20180202.11 T2 - Journal of Biomaterials JF - Journal of Biomaterials JO - Journal of Biomaterials SP - 24 EP - 30 PB - Science Publishing Group SN - 2640-2629 UR - https://doi.org/10.11648/j.jb.20180202.11 AB - In the wake of rising prices and unstable supply besides environmental issues, renewed attention has been paid to shifting away from the use of petroleum based fuels. The world’s energy demand is commencing its dependency on alternative fuels. Such alternative fuels in use today consist of bio-alcohols (such as ethanol), biomass, and natural oil/fat-derived fuels. In search for new energy sources, much attention is focused on biodiesel as a reliable and renewable resource that is to satisfy a significant part of the energy demands. The oil extracted from the dried seeds of Ricinus communis was used in the production of biodiesel under the condition of 3:1 methanol/oil molar ratio for 1hour at 65°C. The biodiesel produced was subjected to physiochemical analysis. The methyl esters produced were found to meet the ASTM standards for biodiesel. The results obtained from analysis of biodiesel from Ricinus communis include free fatty acid: 0.312%; acid value: 0.628mgKOH/g; specific gravity: 0.8937; kinematic velocity: 7.435Cst; refractive index: 1.6254; flash point: 155°C; fire point: 132°C; water content: 3.24%. Thus, the values obtained met with the ASTM standard making the sample a promising potential for biodiesel production. From the result of this work, the oil extracted from the Ricinus communis seed is a potential feedstock for the production of quality biodiesel since almost all the fuel characteristics met the ASTM standards for biodiesel. VL - 2 IS - 2 ER -
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