Effect of Particle Size of Rice-Husk Derived Silica on the Pyrolysis of Pomelo Peels

Bulletin of Chemical Reaction Engineering & Catalysis Pub Date : 2023-09-13 DOI:10.9767/bcrec.19801

Karakate Bo-ongcharoenlab, Iyarin Tongdang, Worapon Kiatkittipong, Adisak Jaturapiree, Kanjarat Sukrat, Thanunya Saowapark, Ekrachan Chaichana

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Abstract

Silica with two different sizes i.e. microsilica (MS) and nanosilica (NS) was used as a catalytic support for vanadium (5-15 wt%) in the pyrolysis of pomelo peels. Besides use of pomelo peels (agricultural residues) as a feedstock for the pyrolysis, to contribute to environmental sustainability, rice husk was used as a silica source for obtaining the silica support. From the result, it was found that non-catalytic pyrolysis of pomelo peels gave a bio-oil yield of 33.3 wt%. The catalytic pyrolysis with vanadium-modified silica decreased the bio-oil yields ranging between 27.2-33.1 wt%. This was due to the occurrence of the second reactions generated from the active sites on the catalysts, which leads to the conversion of bio-oil into gas products. For NS catalyst, increasing the amount of vanadium loading directly decreased the bio-oil yields and increased the gas yield. The variation of product phase distribution was not clearly observed for MS catalyst even with various vanadium loadings. In addition, NS catalyst exhibited higher efficiency in reducing the acid content in the bio-oil, and increasing the phenol content. The distinguished properties of the nanoparticles may be the main reason for these phenomena. Copyright © 2023 by Authors, Published by BCREC Group. This is an open access article under the CC BY-SA License (https://creativecommons.org/licenses/by-sa/4.0).

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稻壳衍生二氧化硅粒度对柚子皮热解的影响

采用微二氧化硅(MS)和纳米二氧化硅(NS)两种不同粒径的二氧化硅作为钒(5-15 wt%)的催化载体进行柚皮热解。除了使用柚子皮(农业残留物)作为热解的原料外，为了促进环境的可持续性，稻壳被用作二氧化硅源以获得二氧化硅载体。结果表明，柚皮非催化热解的生物油收率为33.3%。钒改性二氧化硅催化热解可使生物油收率降低27.2 ~ 33.1%。这是由于催化剂活性位点发生了二次反应，导致生物油转化为气体产品。对于NS催化剂，钒负载量的增加直接降低了生物油收率，提高了生物气收率。在不同的钒负载下，产物相分布的变化也不明显。此外，NS催化剂在降低生物油中的酸含量和提高酚含量方面表现出较高的效率。纳米颗粒的独特性质可能是造成这些现象的主要原因。版权所有©2023作者，BCREC集团出版。这是一篇基于CC BY-SA许可(https://creativecommons.org/licenses/by-sa/4.0)的开放获取文章。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bulletin of Chemical Reaction Engineering & Catalysis

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