Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron
Pyrolysis of biomass converts it to bio-oil, which contains high oxygen content, reactive nature, and poor heating value and hence require upgradation prior to its utilization as fuel. It is desirable to convert the oxygenated compounds of bio-oil into oxygen deficient compounds in the context of co...
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sg-ntu-dr.10356-1399092020-05-22T08:08:37Z Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron Ansari, Khursheed B. Gaikar, Vilas G. School of Chemical and Biomedical Engineering Engineering::Chemical engineering Napier Grass Pyrolysis Bio-oil Pyrolysis of biomass converts it to bio-oil, which contains high oxygen content, reactive nature, and poor heating value and hence require upgradation prior to its utilization as fuel. It is desirable to convert the oxygenated compounds of bio-oil into oxygen deficient compounds in the context of converting biomass to biofuel. In this work, we show the generation of hydrocarbon-rich bio-oil from grassy biomass (taking Napier grass as a model compound) using vacuum pyrolysis coupled with online upgradation (or deoxygenation) of volatile products over an iron bed. A comparison between individual pyrolysis products, especially liquid compounds, without and with vapor upgradation treatment, is presented. Online deoxygenation of pyrolysis volatile products over iron bed significantly reduced oxygenated compounds within bio-oil and increased the formation of hydrocarbons. Pyrolysis gases after deoxygenation treatment predominantly contained hydrogen along with C1 – C4 hydrocarbons, carbon dioxide, and carbon monoxide. Amongst liquid products, bio-oil mainly contained C9 – C23 hydrocarbons, phenols, and aldehydes, while, aqueous phase contained dissolved organics as alcohol, acid, aldehyde, phenolic compounds, and sugar chemicals. Additionally, the amorphous and alkaline biochar comprised of nanoparticles, having the porous surface and various functionalities suitable for acidic soil. Moreover, a reaction scheme for Napier grass-derived products is proposed. 2020-05-22T08:08:36Z 2020-05-22T08:08:36Z 2018 Journal Article Ansari, K. B., & Gaikar, V. G. (2019). Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron. Renewable Energy, 130, 305-318. doi:10.1016/j.renene.2018.06.052 0960-1481 https://hdl.handle.net/10356/139909 10.1016/j.renene.2018.06.052 2-s2.0-85049303236 130 305 318 en Renewable Energy © 2018 Elsevier Ltd. All rights reserved. |
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Engineering::Chemical engineering Napier Grass Pyrolysis Bio-oil |
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Engineering::Chemical engineering Napier Grass Pyrolysis Bio-oil Ansari, Khursheed B. Gaikar, Vilas G. Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron |
| description |
Pyrolysis of biomass converts it to bio-oil, which contains high oxygen content, reactive nature, and poor heating value and hence require upgradation prior to its utilization as fuel. It is desirable to convert the oxygenated compounds of bio-oil into oxygen deficient compounds in the context of converting biomass to biofuel. In this work, we show the generation of hydrocarbon-rich bio-oil from grassy biomass (taking Napier grass as a model compound) using vacuum pyrolysis coupled with online upgradation (or deoxygenation) of volatile products over an iron bed. A comparison between individual pyrolysis products, especially liquid compounds, without and with vapor upgradation treatment, is presented. Online deoxygenation of pyrolysis volatile products over iron bed significantly reduced oxygenated compounds within bio-oil and increased the formation of hydrocarbons. Pyrolysis gases after deoxygenation treatment predominantly contained hydrogen along with C1 – C4 hydrocarbons, carbon dioxide, and carbon monoxide. Amongst liquid products, bio-oil mainly contained C9 – C23 hydrocarbons, phenols, and aldehydes, while, aqueous phase contained dissolved organics as alcohol, acid, aldehyde, phenolic compounds, and sugar chemicals. Additionally, the amorphous and alkaline biochar comprised of nanoparticles, having the porous surface and various functionalities suitable for acidic soil. Moreover, a reaction scheme for Napier grass-derived products is proposed. |
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School of Chemical and Biomedical Engineering |
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School of Chemical and Biomedical Engineering Ansari, Khursheed B. Gaikar, Vilas G. |
| format |
Article |
| author |
Ansari, Khursheed B. Gaikar, Vilas G. |
| author_sort |
Ansari, Khursheed B. |
| title |
Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron |
| title_short |
Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron |
| title_full |
Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron |
| title_fullStr |
Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron |
| title_full_unstemmed |
Investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron |
| title_sort |
investigating production of hydrocarbon rich bio-oil from grassy biomass using vacuum pyrolysis coupled with online deoxygenation of volatile products over metallic iron |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/139909 |
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