A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio
Currently, the biodiesel production technology is moving toward the trend of non-catalytic reaction under subcritical condition as the conventional non-catalytic transesterification requires high energy input and high production cost. Hence, non-catalytic biodiesel production under subcritical condi...
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my.uniten.dspace-240642023-05-29T14:54:59Z A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio Ong M.Y. Salman B. Nor-Insyirah S.A.L. Hussein R. Nomanbhay S. 57191970824 57195282152 57205238179 57204145434 22135844300 Currently, the biodiesel production technology is moving toward the trend of non-catalytic reaction under subcritical condition as the conventional non-catalytic transesterification requires high energy input and high production cost. Hence, non-catalytic biodiesel production under subcritical condition using microwave energy is proposed. Before that, thermogravimetric analysis (TGA) was conducted to characterize the biodiesel feedstock and determine the suitable experimental temperature range for the proposed method. Besides, the thermal behavior of the palm oil and biodiesel at different stages of reaction was also investigated. The results showed that the palm oil and biodiesel were started to degrade from 335�C and 160�C respectively. However, the degradation point of palm oil was higher than the supercritical temperature of DMC. So, external energy is needed to bring down the operating condition, such as microwave energy as it has potential to reduce the activation energy. To further eliminate the problem of biodiesel thermal degradation during the transesterification process, the suggested experimental temperature range is within 80�C to 180�C, which is from the temperature lower than the boiling point of DMC ( < 90�C) to the temperature slightly higher than the biodiesel thermal degradation point. Furthermore, DSC result indicated that palm oil requires 518.35kJ/mol to decompose. � 2018 Authors. Final 2023-05-29T06:54:59Z 2023-05-29T06:54:59Z 2018 Article 10.14419/ijet.v7i4.35.22362 2-s2.0-85059232800 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85059232800&doi=10.14419%2fijet.v7i4.35.22362&partnerID=40&md5=85d9f35aa061cd1e070b84f1544ea5a4 https://irepository.uniten.edu.my/handle/123456789/24064 7 4 190 193 All Open Access, Bronze, Green Science Publishing Corporation Inc Scopus |
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Currently, the biodiesel production technology is moving toward the trend of non-catalytic reaction under subcritical condition as the conventional non-catalytic transesterification requires high energy input and high production cost. Hence, non-catalytic biodiesel production under subcritical condition using microwave energy is proposed. Before that, thermogravimetric analysis (TGA) was conducted to characterize the biodiesel feedstock and determine the suitable experimental temperature range for the proposed method. Besides, the thermal behavior of the palm oil and biodiesel at different stages of reaction was also investigated. The results showed that the palm oil and biodiesel were started to degrade from 335�C and 160�C respectively. However, the degradation point of palm oil was higher than the supercritical temperature of DMC. So, external energy is needed to bring down the operating condition, such as microwave energy as it has potential to reduce the activation energy. To further eliminate the problem of biodiesel thermal degradation during the transesterification process, the suggested experimental temperature range is within 80�C to 180�C, which is from the temperature lower than the boiling point of DMC ( < 90�C) to the temperature slightly higher than the biodiesel thermal degradation point. Furthermore, DSC result indicated that palm oil requires 518.35kJ/mol to decompose. � 2018 Authors. |
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57191970824 Ong M.Y. Salman B. Nor-Insyirah S.A.L. Hussein R. Nomanbhay S. |
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Ong M.Y. Salman B. Nor-Insyirah S.A.L. Hussein R. Nomanbhay S. |
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Ong M.Y. Salman B. Nor-Insyirah S.A.L. Hussein R. Nomanbhay S. A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio |
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Ong M.Y. |
| title |
A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio |
| title_short |
A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio |
| title_full |
A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio |
| title_fullStr |
A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio |
| title_full_unstemmed |
A preliminary experiment of non-catalytic transesterification: Thermal analysis of palm oil and biodiesel at different ratio |
| title_sort |
preliminary experiment of non-catalytic transesterification: thermal analysis of palm oil and biodiesel at different ratio |
| publisher |
Science Publishing Corporation Inc |
| publishDate |
2023 |
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1806426174383980544 |