Hydrothermal carbonization of snow crab processing by-product: Hydrochar characterization

IF 5.8 2区 化学 Q1 CHEMISTRY, ANALYTICAL
Nadyana Incan , Kelly A. Hawboldt , Stephanie MacQuarrie
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引用次数: 0

Abstract

Fishery processing (crab) is an important industry in Atlantic Canada. However, up to half of the landed product ends as processing by-product with over 70 wt% water content. Often regarded as a “waste” this by-product has applications in soils, wastewater treatment, and other industries, an area of research largely unexplored. Hydrothermal carbonization (HTC) converts biomass into a more stable and useable material (hydrochar) and uses water as a medium. This valorization not only creates a profit stream but also reduces the environmental impacts of the crab by-product treatment and disposal. In this work, HTC hydrochar from snow crab (Chionoecetes opilio) processing by-product/feedstock is characterized with respect to key properties in an effort to delineate potential end use applications and the impact of process parameters (temperature, residence time, and water to biomass ratio) on these properties. The temperature range was 180–260 ℃, residence time of 0.5–3 h, and water to biomass ratio of 2–4 (wt:wt). The solids yield decreased as water ratio and temperature increased (time did not impact yield to the same extent). The hydrochar ash content increased from 33 to 45 wt% as water ratio and temperature increased to the maximums studied in this work. XRD analysis showed that the hydrochar retained chitin and CaCO3. Trace analysis showed calcium was the most abundant mineral in the feedstock and hydrochar, consistent with the XRD CaCO3 peak. Compared to the feedstock (11 m2/g), the hydrochar BET surface area increased with temperature and water ratio, reaching a maximum of 26 m2/g at 260 °C, water ratio 3 and 30 min. However, increasing the time to 3 h reduced the surface area to 13.47 m2/g. Hydrochar carbon content is similar or slightly higher than the feedstock due to competing polymerization reaction and CaCO3 dissolution. Nitrogen decreased as temperature increased possibly due to protein degradation. Hydrochar and feedstock showed similar functional groups. The functional groups in the hydrochar have potential to facilitate chemosorption as a bioadsorbent.
雪蟹加工副产品的水热碳化:水碳特征
渔业加工(螃蟹)是加拿大大西洋地区的重要产业。然而,多达一半的上岸产品最终成为含水量超过 70 wt% 的加工副产品。这种副产品通常被视为 "废物",可用于土壤、废水处理和其他行业,但这一研究领域在很大程度上尚未开发。水热碳化(HTC)将生物质转化为更稳定、更可用的材料(水炭),并以水为介质。这种增值不仅创造了利润流,还减少了螃蟹副产品处理和处置对环境的影响。在这项工作中,对来自雪蟹(Chionoecetes opilio)加工副产品/原料的 HTC 水炭的主要特性进行了表征,以确定潜在的最终用途以及工艺参数(温度、停留时间和水与生物质比率)对这些特性的影响。温度范围为 180-260 ℃,停留时间为 0.5-3 h,水与生物质比率为 2-4(重量比)。固体产量随着水比和温度的增加而减少(时间对产量的影响程度不同)。随着水比和温度的增加,水煤灰含量从 33% 增加到 45%,达到了本次研究的最大值。XRD 分析表明,水碳保留了甲壳素和 CaCO3。痕量分析表明,钙是原料和水碳中含量最高的矿物质,这与 XRD CaCO3 峰值一致。与原料(11 m2/g)相比,水炭的 BET 表面积随温度和水比率的增加而增加,在 260 °C、水比率 3 和 30 分钟时达到最大值 26 m2/g。然而,将时间延长至 3 小时后,表面积降至 13.47 m2/g。由于竞争性聚合反应和 CaCO3 的溶解,水碳的碳含量与原料相近或略高于原料。氮含量随着温度的升高而降低,这可能是由于蛋白质降解所致。水碳和原料显示出相似的官能团。作为一种生物吸附剂,水碳中的官能团具有促进化学吸附的潜力。
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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来源期刊
CiteScore
9.10
自引率
11.70%
发文量
340
审稿时长
44 days
期刊介绍: The Journal of Analytical and Applied Pyrolysis (JAAP) is devoted to the publication of papers dealing with innovative applications of pyrolysis processes, the characterization of products related to pyrolysis reactions, and investigations of reaction mechanism. To be considered by JAAP, a manuscript should present significant progress in these topics. The novelty must be satisfactorily argued in the cover letter. A manuscript with a cover letter to the editor not addressing the novelty is likely to be rejected without review.
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