Properties of Upgraded Bio-oil from Pyrolysis of Waste Corn Cobs

Abatyough, Michael Terungwa; Ajibola, V.O.; Agbaji, E. B.; Yashim, Zakka Israila

doi:10.3126/josem.v1i2.45348

Cited by 9 publications

(5 citation statements)

References 34 publications

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“…Similarly, for sunflower, the compounds with the highest percentages were identified as isoprimaric acid (9.23%), albietic acid (4.93%), and palmitic acid (4.86%). The results confirm a similar chemical composition of the bio-oils from the selected biomass types compared to other studies [47,48], indicating high concentrations of acids. The higher catechol content in the vine rod samples could be indicative of its chemical composition, as certain compounds tend to yield specific by-products during pyrolysis.…”

Section: Analysis Of Organic Compounds In Pyrolysis Oils Of Corn Cob ...supporting

confidence: 87%

Exploring the Potential of Biomass Pyrolysis for Renewable and Sustainable Energy Production: A Comparative Study of Corn Cob, Vine Rod, and Sunflower

Domazetovska,

Strezov,

Filkoski

et al. 2023

Sustainability

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The paper investigates the potential of biomass pyrolysis as a sustainable and renewable energy solution. The study focuses on three biomass types: corn cob, vine rod, and sunflower, which are abundant agricultural residues with potential for biofuel production. The pyrolytic gas, oil, and char produced during pyrolysis at a heating rate of 10 °C/min were analyzed. At the pyrolysis temperature of 500 °C, the corn cob showed the smallest final residual mass of 24%, while the vine rod exhibited the largest mass loss of 40%. Gas analysis revealed the concentrations of CO2, CO, H2, and CH4 in the pyrolytic gas, indicating its energy potential. Sunflower presented the largest calorific value of the produced biogas, while corn cob was the lowest. The chemical composition of the bio-oils was determined, with aliphatic acids identified as the dominant compounds, suggesting their potential for biodiesel production. Fourier Transform–Infrared Spectroscopy (FT-IR) analysis of raw biomass and char products demonstrated varying extents of decomposition among the biomass samples. A multicriteria assessment approach was employed to evaluate the differences between the selected three biomass feedstock and determined that sunflower biomass ranked the highest among the three, although the overall difference was small, confirming the suitability of all three biomass samples for pyrolysis conversion to higher-value-added fuels.

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Section: Analysis Of Organic Compounds In Pyrolysis Oils Of Corn Cob ...supporting

confidence: 87%

Exploring the Potential of Biomass Pyrolysis for Renewable and Sustainable Energy Production: A Comparative Study of Corn Cob, Vine Rod, and Sunflower

Domazetovska,

Strezov,

Filkoski

et al. 2023

Sustainability

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“…The biomass investigated had low ash content (AC) except for lemongrass which had an AC of 17.2%. This was higher than the 7.02% reported for lemongrass by Madhu et al The ACs in the present study for corncob (1.32%), groundnut shell (1.21%), and sawdust (1.53%) were comparable with the findings of 1.05, , 1.3, and 1.13%, respectively. Biomass ash consists primarily of oxide forms of silica, aluminum, titanium, potassium, iron, magnesium, and sodium .…”

Section: Resultssupporting

confidence: 50%

Comprehensive Characterization of Some Selected Biomass for Bioenergy Production

Yahya,

Adeleke,

Nzerem

et al. 2023

ACS Omega

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There is a lack of information about the detailed characterization of biomass of Nigerian origin. This study presents a comprehensive characterization of six biomass, groundnut shells, corncob, cashew leaves, Ixora coccinea (flame of the woods), sawdust, and lemongrass, to aid appropriate selection for bio-oil production. The proximate, ultimate, calorific value and compositional analyses were carried out following the American Standard for Testing and Materials (ASTM) standards. Fourier transform infrared spectroscopy, thermogravimetric analysis, scanning electron microscopy with energy-dispersive X-ray spectroscopy, and Xray fluorescence were employed in this study for functional group analyses, thermal stability, and structural analyses. The H/C and O/C atomic ratios, fuel ratio, ignitability index, and combustibility index of the biomass samples were evaluated. Groundnut shells, cashew leaves, and lemongrass were identified as promising feedstocks for bio-oil production based on their calorific values (>20 MJ/kg). Sawdust exhibited favorable characteristics for bio-oil production as indicated by its higher volatile matter (79.28%), low ash content (1.53%), low moisture content (6.18%), and high fixed carbon content (13.01%). Also, all samples showed favorable ignition and flammability properties. The low nitrogen (<0.12%) and sulfur (<0.04%) contents in the samples make them environmentally benign fuels as a lower percentage of NO x and SO x will be released during the production of the bio-oil. These results are contributions to the advancement of a sustainable and efficient carbon-neutral energy mix, promoting biomass resource utilization for the generation of energy.

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“…The more the fuel's calorie content, the more efficient the energy produced because it generates more heat with less mass. The high energy value reflected the carbon-tohydrogen ratio in the Biofuel [47].…”

Section: Biofuel Calorific Value Analysismentioning

confidence: 99%

Biofuel Production from Rubber Seeds by Pyrolysis Method using Natural Zeolite Catalyst

Yerizam,

Hasan,

Lestari

et al. 2023

ijmst

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Rubber seed is rubber plant waste that has the potential as a source of bioenergy. Rubber seed contains 40-50% oil, and rubber seed shell contains lignocellulose (cellulose, hemicellulose, and lignin). Rubber and rubber seed shells can be converted into biofuel through the Pyrolysis Process. Pyrolysis is biomass decomposition with heat assistance without oxygen at 250oC-600oC. This research aimed to analyze the characteristics of biofuel products. This research was conducted using a pyrolysis reactor by controlling the temperature at 250oC, 300oC, 350oC, 400oC, and 450oC. The characteristics of biofuel produced in this study include density (1.0646 gr/ml), viscosity (5.417 mm2/s), flash point (88ºC), moisture content (30.4%), calorific value (7451.3997 Cal/g), and cetane number (32.9). Based on the results of biofuel analysis using GC-MS, the C atom chain was dominated by C5-C15 compounds at 44.41%.

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Properties of Upgraded Bio-oil from Pyrolysis of Waste Corn Cobs

Cited by 9 publications

References 34 publications

Exploring the Potential of Biomass Pyrolysis for Renewable and Sustainable Energy Production: A Comparative Study of Corn Cob, Vine Rod, and Sunflower

Exploring the Potential of Biomass Pyrolysis for Renewable and Sustainable Energy Production: A Comparative Study of Corn Cob, Vine Rod, and Sunflower

Comprehensive Characterization of Some Selected Biomass for Bioenergy Production

Biofuel Production from Rubber Seeds by Pyrolysis Method using Natural Zeolite Catalyst

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