Thermogravimetric characteristics and predictive modelling of oil sand bitumen pyrolysis using artificial neural network

被引:0
作者
Festus M. Adebiyi [1 ]
Odunayo T. Ore [2 ]
Oluwagbenga E. Aderibigbe [1 ]
机构
[1] Obafemi Awolowo University,Department of Chemistry
[2] Kogi State University,Department of Chemistry and Industrial Chemistry
来源
Discover Energy | / 4卷 / 1期
关键词
Artificial neural network; Kinetics; Oil sand bitumen; Pyrolysis; Thermodynamics;
D O I
10.1007/s43937-024-00045-5
中图分类号
学科分类号
摘要
This study investigated the pyrolysis of oil sand bitumen as an alternative energy source in response to the global energy crisis. Thermogravimetric analysis was performed at different heating rates in a nitrogen atmosphere. Low moisture and ash content and high volatile matter content were found by proximate analysis, indicating the possibility for effective pyrolysis and ignition. Fourier-transform infrared spectroscopy identified functional groups, and X-ray diffraction confirmed the absence of problematic expandable clay minerals. The Friedman, Flynn–Wall–Ozawa, and Kissinger–Akahira–Sunose models were used to calculate the kinetic parameters. The activation energies of the models were primarily between 100 and 200 kJ/mol, with the Friedman model having higher values. It was discovered that the process was non-spontaneous and endothermic. An artificial neural network model demonstrated the potential for future energy applications by accurately predicting the behaviour of pyrolysis.
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  • [1] Zhang Y(2019)Comparative kinetics of coal and oil shale pyrolysis in a micro fluidized bed reaction analyzer Carbon Resour Convers 2 217-224
  • [2] Zhao M(2014)Shrinkage kinetics of large-sized briquettes during pyrolysis and its application in tamped coal cakes from large-scale chambers Fuel 138 1-14
  • [3] Linghu R(2017)Thermal cracking characteristics and kinetics of oil sand bitumen and its SARA fractions by TG–FTIR Energy Fuels 31 1295-1309
  • [4] Wang C(2017)Chemical analysis of resin fraction of Nigerian bitumen for organic and trace metal compositions Pet Sci Technol 35 1370-1380
  • [5] Zhang S(2021)EDXRF analysis and risks assessment of potentially toxic elements in sand fraction (tailing) of Nigerian oil sands Energy Ecol Environ 6 258-270
  • [6] Wang Q(2024)Distribution, health and ecological risk assessments of trace elements in Nigerian oil sands Acta Geochimica 43 59-71
  • [7] Zhao Y(2021)Toxic metals in oil sands: review of human health implications, environmental impact, and potential remediation using membrane-based approach Energy Ecol Environ 6 81-91
  • [8] Zhang Y(2021)A review on current trends and prospects in the pyrolysis of heavy oils J Petroleum Explor Prod 11 1521-1530
  • [9] Hao J(2018)Kinetics of the pyrolysis of oil sands based upon thermogravimetric analysis Thermochim Acta 666 66-74
  • [10] Che Y(2023)Thermo-mineralization of biomass for metal oxide recovery: a review Bioresour Technol Rep 24 101664-419
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