Thermal and Catalytic Pyrolysis Process of Neem Seed to Produce Valuable Fuels over RFCC Catalyst: Process Development and Evaluation

In this research, thermal and catalytic pyrolysis of neem seed as a non‐edible feed has been investigated for the production of valuable chemicals including bio‐oil, bio‐char and bio‐gas. The sensitivity analysis of main operating parameters of thermal pyrolysis process including temperature (350–55...

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Bibliographic Details
Published in:ChemistrySelect (Weinheim) 2022-03, Vol.7 (11), p.n/a
Main Authors: Zhandnezhad, Alireza, Saidi, Majid, Taheri Najafabadi, Ali
Format: Article
Language:English
Subjects:
Bio-oil
Biomass
Neem seed
Pyrolysis
RFCC catalyst
Upgrading
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Summary:In this research, thermal and catalytic pyrolysis of neem seed as a non‐edible feed has been investigated for the production of valuable chemicals including bio‐oil, bio‐char and bio‐gas. The sensitivity analysis of main operating parameters of thermal pyrolysis process including temperature (350–550 °C), reaction time (30–180 min) and heating rate (10–40 °C/min) on the major products yield has been performed and the optimum operating condition to maximize the bio‐oil production has been determined. The achieved results indicated that the maximum bio‐oil production yield is obtained at temperature of 450 °C. The bio‐oil production yield enhances with increasing the heating rate, whereas the process time in the considered range has not significant effect on the bio‐oil production yield. Since the main focus of this study was catalytic upgrading of pyrolysis‐derived bio‐oil to valuable fuels, catalytic pyrolysis of neem seeds over industrial RFCC catalyst has been examined using different catalyst loading in the range of 10–40 wt %. It is inferred that more aromatic compounds will be generated with increasing the RFCC catalyst loading which could be attributed to the presence of Al2O3 and zeolite in the catalyst structure. Also, the bio‐oil and bio‐gas production yields via catalytic pyrolysis process over 20 wt. % RFCC catalyst enhanced from 44.3 % to 49.5 % and 22.4 % to 27 % with increasing temperature from 350 and 450 °C, respectively. Catalytic pyrolysis of neem seed was performed to produce valuable fuel. The catalytic activity of RFCC catalyst was evaluated and the sensitivity analysis of operating condition on the bio‐oil production yield was studied. More aromatic compounds were formed with increasing RFCC catalyst loading which could be attributed to the presence of Al2O3 and zeolite in the catalyst structure. Investigation of pyrolysis process over RFCC catalyst could help to attain an optimum design for developing the pyrolysis process in industrial scale.
ISSN:2365-6549
2365-6549
DOI:10.1002/slct.202104480