Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell

Environmental pollution and the declining global supply of accessible fossil fuels are the key drivers of the search for alternative sources of energy. Biodiesel, a renewable liquid transport fuel, is commercially-produced using heterogeneous catalysts. Heterogeneous catalysts obtained from seashell...

Full description

Bibliographic Details
Main Authors: Mazaheri, Hoora, Ong, Hwai Chyuan, Masjuki, Haji Hassan, Amini, Zeynab, Harrison, Mark D., Wang, Chin Tsan, Kusumo, Fitranto, Alwi, Azham
Format: Article
Published: Elsevier 2018
Subjects:
_version_ 1796961407345885184
author Mazaheri, Hoora
Ong, Hwai Chyuan
Masjuki, Haji Hassan
Amini, Zeynab
Harrison, Mark D.
Wang, Chin Tsan
Kusumo, Fitranto
Alwi, Azham
author_facet Mazaheri, Hoora
Ong, Hwai Chyuan
Masjuki, Haji Hassan
Amini, Zeynab
Harrison, Mark D.
Wang, Chin Tsan
Kusumo, Fitranto
Alwi, Azham
author_sort Mazaheri, Hoora
collection UM
description Environmental pollution and the declining global supply of accessible fossil fuels are the key drivers of the search for alternative sources of energy. Biodiesel, a renewable liquid transport fuel, is commercially-produced using heterogeneous catalysts. Heterogeneous catalysts obtained from seashells appeared as promising alternatives thanks to their low preparation cost and increased efficiency in transesterification. In this study, shells from Chicoreus brunneus (known as Adusta murex) were calcined, hydrated, and dehydrated to produce CaO heterogeneous nanocatalyst for the transesterification of rice bran oil into biodiesel. Field emission scanning electron microscopy, Fourier transform infrared spectroscopy, transmission electron microscopy, surface area measurement (Brunauer-Emmett-Teller method), and X-ray diffraction were used to characterise the seashell-derived catalyst. The properties of the rice bran oil-derived biodiesel (acid value, calorific value, density, oxidation stability, and flash point) conformed to the American Society of Testing and Materials (ASTM) D6751 and European EN 14214 biodiesel standards, except for kinematic viscosity. Therefore, the impact of the parameters used for production of the CaO heterogeneous nanocatalyst (calcination temperature and time) and the transesterification reaction (catalyst loading and methanol to rice bran oil ratio) on the kinematic viscosity of RBO-derived biodiesel were determined. A model for the transesterification process was developed using a combination of artificial neural networking with ant colony optimisation. The model predicted that C. brunneus-derived CaO catalyst prepared at 1100 °C for 72 min could be used to produce biodiesel from rice bran oil with a minimum kinematic viscosity (4.42 mm2 s−1) confirming to both the ASTM D6751 and EN 14214 biodiesel standards in a transesterification reaction operating with a 35:1 methanol to rice bran oil molar ratio and 0.5 wt% catalyst mass.
first_indexed 2024-03-06T05:53:47Z
format Article
id um.eprints-21311
institution Universiti Malaya
last_indexed 2024-03-06T05:53:47Z
publishDate 2018
publisher Elsevier
record_format dspace
spelling um.eprints-213112019-10-24T03:11:58Z http://eprints.um.edu.my/21311/ Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell Mazaheri, Hoora Ong, Hwai Chyuan Masjuki, Haji Hassan Amini, Zeynab Harrison, Mark D. Wang, Chin Tsan Kusumo, Fitranto Alwi, Azham TJ Mechanical engineering and machinery Environmental pollution and the declining global supply of accessible fossil fuels are the key drivers of the search for alternative sources of energy. Biodiesel, a renewable liquid transport fuel, is commercially-produced using heterogeneous catalysts. Heterogeneous catalysts obtained from seashells appeared as promising alternatives thanks to their low preparation cost and increased efficiency in transesterification. In this study, shells from Chicoreus brunneus (known as Adusta murex) were calcined, hydrated, and dehydrated to produce CaO heterogeneous nanocatalyst for the transesterification of rice bran oil into biodiesel. Field emission scanning electron microscopy, Fourier transform infrared spectroscopy, transmission electron microscopy, surface area measurement (Brunauer-Emmett-Teller method), and X-ray diffraction were used to characterise the seashell-derived catalyst. The properties of the rice bran oil-derived biodiesel (acid value, calorific value, density, oxidation stability, and flash point) conformed to the American Society of Testing and Materials (ASTM) D6751 and European EN 14214 biodiesel standards, except for kinematic viscosity. Therefore, the impact of the parameters used for production of the CaO heterogeneous nanocatalyst (calcination temperature and time) and the transesterification reaction (catalyst loading and methanol to rice bran oil ratio) on the kinematic viscosity of RBO-derived biodiesel were determined. A model for the transesterification process was developed using a combination of artificial neural networking with ant colony optimisation. The model predicted that C. brunneus-derived CaO catalyst prepared at 1100 °C for 72 min could be used to produce biodiesel from rice bran oil with a minimum kinematic viscosity (4.42 mm2 s−1) confirming to both the ASTM D6751 and EN 14214 biodiesel standards in a transesterification reaction operating with a 35:1 methanol to rice bran oil molar ratio and 0.5 wt% catalyst mass. Elsevier 2018 Article PeerReviewed Mazaheri, Hoora and Ong, Hwai Chyuan and Masjuki, Haji Hassan and Amini, Zeynab and Harrison, Mark D. and Wang, Chin Tsan and Kusumo, Fitranto and Alwi, Azham (2018) Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell. Energy, 144. pp. 10-19. ISSN 0360-5442, DOI https://doi.org/10.1016/j.energy.2017.11.073 <https://doi.org/10.1016/j.energy.2017.11.073>. https://doi.org/10.1016/j.energy.2017.11.073 doi:10.1016/j.energy.2017.11.073
spellingShingle TJ Mechanical engineering and machinery
Mazaheri, Hoora
Ong, Hwai Chyuan
Masjuki, Haji Hassan
Amini, Zeynab
Harrison, Mark D.
Wang, Chin Tsan
Kusumo, Fitranto
Alwi, Azham
Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell
title Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell
title_full Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell
title_fullStr Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell
title_full_unstemmed Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell
title_short Rice bran oil based biodiesel production using calcium oxide catalyst derived from Chicoreus brunneus shell
title_sort rice bran oil based biodiesel production using calcium oxide catalyst derived from chicoreus brunneus shell
topic TJ Mechanical engineering and machinery
work_keys_str_mv AT mazaherihoora ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell
AT onghwaichyuan ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell
AT masjukihajihassan ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell
AT aminizeynab ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell
AT harrisonmarkd ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell
AT wangchintsan ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell
AT kusumofitranto ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell
AT alwiazham ricebranoilbasedbiodieselproductionusingcalciumoxidecatalystderivedfromchicoreusbrunneusshell