Browse > Article
http://dx.doi.org/10.14478/ace.2022.1086

In situ Transesterification/Reactive Extraction of Castor Bean Seeds Assisted by Flying Jet Plasma for Biodiesel Production  

Elsheikh, Yasir A. (Department of Chemical and Petrochemical Engineering, University of Nizwa)
Abdul-Majeed, Wameath S. (Department of Chemical and Petrochemical Engineering, University of Nizwa)
Nasir, Qazi (Department of Chemical and Petrochemical Engineering, University of Nizwa)
Al-Rahbi, Balaqis (Department of Chemical and Petrochemical Engineering, University of Nizwa)
Al-Subhi, Noor (Department of Chemical and Petrochemical Engineering, University of Nizwa)
Mahmoud, Mohamed A. (Chemical Engineering Department, College of Engineering, Jazan University)
AAl-Thani, Ghanim S. (Daris Centre for Scientific Research and Technological Development, University of Nizwa)
Publication Information
Applied Chemistry for Engineering / v.33, no.5, 2022 , pp. 538-544 More about this Journal
Abstract
One of the most exciting areas for the development of alternative fuels is the production of biodiesel. To reduce the cost of biodiesel production, in situ trans-esterification has been introduced to simplify the production process by enabling extraction and trans-esterification to occur at a single stage in the presence of a catalyst. In this study, we investigated the feasibility of using non-corrosive and environmentally receptive flying jet plasma as an alternative catalytic route for in situ tran-sesterification of castor bean seeds (CBS). Upon optimizing the reaction conditions, it is elucidated that applying a low ratio of methanol to seeds (≤6:1) has resulted in hindering the in situ trans-esterification and leading to insignificant conversion. The yield of esters has increased from 80.5% to 91.7% as the molar ratio rose from 9:1 to 12:1. Excess alcohol beyond the ratio of 15:1 was shown to have a negative impact on the yield of the produced esters, attributed to an increase in the biodiesel portion prone to dissolving in the co-product (glycerol). An increase in the reaction bulk temperature from 40 to 55 ℃ led to a higher ester content by 50%. Further increases in the bulk temperature beyond 55 ℃ did not affect yields. Regarding the reaction period, the results have shown that 3 h of reaction is adequate for a higher biodiesel yield. The quality of the biodiesel obtained has demonstrated that all physicochemical properties meet the ASTM D6751 specifications.
Keywords
Flying jet plasma; In situ transesterification; Reaction mechanism; Biodiesel; Chromatographic analyses;
Citations & Related Records
연도 인용수 순위
  • Reference
1 D. Leung and Y. Guo, Transesterification of neat and used frying oil: Optimization for biodiesel production, Fuel Process Technol., 87, 883-890 (2006).   DOI
2 L. C. Meher, D. V. Sagar, and S. N. Naik, Technical aspects of biodiesel production by transesterification - A review, Renew. Sust. Energ. Rev., 10, 248-268 (2006).   DOI
3 B. P. Thangaraj, R. Solomon, B. Muniyandi, S. Ranganathan, and L. Lin, Catalysis in biodiesel production-A review, Clean Energy, 3, 2-23 (2019).   DOI
4 J. Li, C. Ma, S. Zhu, F. Yu, B. Dai, and D. Yang, A review of recent advances of dielectric barrier discharge plasma in catalysis, Nanomaterials, 9, 1-34 (2019).   DOI
5 F. Kasim, A. P. Harvey, and R. Zakaria, Biodiesel production by in situ transesterification, Biofuels, 1, 355-365 (2014).   DOI
6 M. J. Haas, K. M. Scott, T. A. Foglia, and W. N. Marmer, The general applicability of in situ transesterification for the production of fatty acid esters from a variety of feedstocks, JAOCS, 84, 963-970 (2007).   DOI
7 P. Mehta, P. Barboun, D. B. Go, J. C. Hicks, and W. F. Schneider, Catalysis enabled by plasma activation of strong chemical bonds: A review, ACS Energy Lett., 4, 1115-1133 (2019).   DOI
8 W. S. Abdul-Majeed, G. S. AAl-Thani, and J. N. Al-Sabahi, Application of flying jet plasma for production of biodiesel fuel from wasted vegetable oil, Plasma Chem. Plasma Process., 36, 1517-1531 (2016).   DOI
9 Y. Zhang, M. A. Dube, D. D. McLean, and M. Kates, Biodiesel production from waste cooking oil: Economic assessment and sensitivity analysis, Bioresour. Technol., 90, 229-240 (2003).   DOI
10 W. S. Abdul-Majeed, and K.O. Al-Riyami, Activation of peat soil carbon and production of carbon nanostructures using a flying jet cold plasma torch, Environ. Chem. Lett., 17, 1383-1390 (2019).   DOI
11 U. Kogelschatz, Dielectric-barrier discharges: their history, discharge physics, and industrial applications, Plasma Chem. Plasma Process., 23, 1-46 (2003).   DOI
12 R.S. Singhal and P. R. Kulkarni, Effect of puffing on oil characteristics of Amaranth (Rajgeera) seeds, JAOCS, 67, 952-954 (1990).   DOI
13 P. Golay, F. Dionisi, B. Hug, and F. Giuffrida, Destaillats, Direct quantification of fatty acids in dairy powders with special emphasis on trans fatty acid content, Food Chem., 101, 1115-1120 (2006).   DOI
14 W. S. Abdul-Majeed, Flying jet plasma: a logistic powerful catalyzing agent for chemical and biological processes, AOCS, 29, 18-20 (2018).
15 Y. A. Elsheikh, Z. Man, M. A. Bustam, F. H. Akhtar, S. Yusup, and A. muhammad, Preparation and characterization of citrulus colocynthis oil biodiesel: Optimization of alkali-catalyzed transesterification, Can. J. Chem. Eng., 92, 435-440 (2014).   DOI
16 U. Rashid, F. Anwar, R. Yunus, and A. H. AL-Muhtaseb, Transesterification for biodiesel production using thespesiapopulnea seed oil: An optimization study, Int. J. Green Energy, 12, 479-484 (2015).   DOI
17 S. M. Sadrameli, and M. Omarei, Preparation of biodiesel by transesterification of canola oil using solid base catalyst KOH/γ-Al2O3, Energy Technology: Carbon Dioxide Management and Other Technologies, 141-148 (2012).   DOI
18 Y. Wang, S. Ou, P. Liu, and Z. Zhang, Preparation of biodiesel from waste cooking oil via two-step catalyzed process, Energy Convers. Manag., 48, 184-188 (2007).   DOI
19 A. Bogaerts, and E. C. Neyts, Plasma technology: An emerging technology for energy storage, ACS Energy Lett., 3, 1013-1027 (2018).   DOI
20 U. Pal, M. Kumar, M. Tyagi, B. Meena, H. Khatun, and A. Sharma, Discharge analysis and electrical modeling for the development of efficient dielectric barrier discharge, J. Phys. Conf. Ser., 208, 1-12 (2010).
21 E. C. Neyts, Plasma-surface interactions in plasma catalysis, Plasma Chem. Plasma Process, 36, 185-212 (2016).   DOI
22 L. Naik, N. Radhika, K. Sravani, A. Hareesha, B. Mohanakumari, and K. Bhavanasindhu, Optimized parameters for production of biodiesel from fried oil, IARJSET, 2, 62-65 (2015).
23 B. R. Dhar, and K. Kirtania, Excess methanol recovery in biodiesel production process using a distillation column: A simulation study, Chem. Eng. Res. Bull., 13, 55-60 (2009).
24 I. S. Sulaiman, M. Basri, H. R. Masoumi, W. J. Chee, S. E. Ashari, and M. Ismail, Effects of temperature, time, and solvent ratio on the extraction of phenolic compounds and the anti-radical activity of Clinacanthusnutans Lindau leaves by response surface methodology, Chem. Cent. J., 54, 1-11 (2017).