Plasma Gasification of a Simulated Low-Level Radioactive Waste: Co, Cs, Sr, and Ce Retention Efficiency

IF 2.8 4区工程技术 Q2 ENGINEERING, CHEMICAL

Processes Pub Date : 2024-09-06 DOI:10.3390/pr12091919

Juan Ariel Pullao, Franco Emmanuel Benedetto, Gian Franco Binetti Basterrechea, Leonardo Andrés Neira Poblete, Diana Carolina Lago, Miguel Oscar Prado

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引用次数: 0

Abstract

Thermal plasma is a versatile technology that can be used to treat various types of wastes, including vegetal and mineral oils, solvents, plastics, paper and cardboard, glasses, bricks and rocks, metals, clothes, and mixtures of these materials. In this study, we utilized a commercial plasma cutter as a thermal plasma source to decrease the volume of a simulated low-level radioactive mixed solid waste. The simulated waste included papers, plastics, clothes, gloves, metals, and stable Co, Cs, Sr, and Ce additives as surrogates of 60Co, 137Cs, 90Sr, and 144Ce, respectively, the latter being typical contaminants in nuclear LLW. As a result of the process, two products were obtained: a solid phase, on which we focused this work, and a gaseous phase. To retain as many as surrogates as possible in the solid final phase, crushed glass from broken bottles was included as a vitrification additive to the original waste. After undergoing heat treatment, a dense vitreous slag was produced along with ashes. The process resulted in a volume reduction of 70%, indicating the successful gasification of organic excess materials. The surrogate elements were retained in the process and were found in the ashes composition: Co (3.4% w/w), Cs (37.7% w/w), and Ce (0.6% w/w) and in the glass matrix composition of Co, Cs, Sr and Ce: 72.4 ± 14.7, 32 ± 18.2, 125.3 ± 31.6, 80 ± 13.1% w/w, respectively. For the actual experimental conditions, retention efficiencies were estimated for cobalt (Co) at 72.4 ± 14.7%, cerium (Ce) at 80 ± 13.1%, strontium (Sr) at 125.3 ± 31.6%, and notably cesium (Cs) at 32 ± 18.2%.

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模拟低放射性废物的等离子气化：钴、铯、锶和铈的保留效率

热等离子体是一种用途广泛的技术，可用于处理各种类型的废物，包括植物油和矿物油、溶剂、塑料、纸张和纸板、玻璃、砖块和岩石、金属、衣物以及这些材料的混合物。在这项研究中，我们利用商用等离子切割机作为热等离子源，减少了模拟低放射性混合固体废物的体积。模拟废物包括纸张、塑料、衣服、手套、金属以及稳定的 Co、Cs、Sr 和 Ce 添加剂，分别作为 60Co、137Cs、90Sr 和 144Ce 的替代物，后者是核低放废物中的典型污染物。在这一过程中，我们获得了两种产品：固相和气相。为了在最终固相中保留尽可能多的代用品，我们在原始废物中加入了碎玻璃作为玻璃化添加剂。经过热处理后，产生了致密的玻璃渣和灰烬。这一过程使体积减少了 70%，表明有机过剩材料的气化取得了成功。该工艺保留了代用元素，并在灰烬成分中发现了这些元素：钴（3.4% w/w）、铯（37.7% w/w）和硒（0.6% w/w），以及玻璃基质中的钴、铯、锶和硒：72.4±14.7、32±18.2、125.3±31.6、80±13.1% w/w。在实际实验条件下，钴（Co）的保留效率估计为 72.4 ± 14.7%，铈（Ce）的保留效率估计为 80 ± 13.1%，锶（Sr）的保留效率估计为 125.3 ± 31.6%，铯（Cs）的保留效率估计为 32 ± 18.2%。

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来源期刊

Processes Chemical Engineering-Bioengineering

CiteScore

5.10

自引率

11.40%

发文量

2239

审稿时长

14.11 days

期刊介绍： Processes (ISSN 2227-9717) provides an advanced forum for process related research in chemistry, biology and allied engineering fields. The journal publishes regular research papers, communications, letters, short notes and reviews. Our aim is to encourage researchers to publish their experimental, theoretical and computational results in as much detail as necessary. There is no restriction on paper length or number of figures and tables.