用于处理受 PFAS 污染水体的传统和新兴 PFAS 选择性阴离子交换树脂的再生技术

IF 8.1 1区 工程技术 Q1 ENGINEERING, CHEMICAL
Anderson C. Ellis , Treavor H. Boyer , Timothy J. Strathmann
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引用次数: 0

摘要

阴离子交换树脂(AER)与传统的活性炭吸附剂相比,具有更高的选择性和能力,因此已成为一种很有前途的分离技术,可用于修复受 PFAS 污染的水体。目前,现场管理人员会在采用被定义为 "可再生 "且 PFAS 选择性相对较低的树脂的 AER 系统和作为 "一次性 "介质销售的 PFAS 选择性树脂之间做出选择,后者的目的是在 PFAS 暴露后进行处置。然而,这些高选择性吸附剂的再生和/或再利用潜力仍鲜为人知。本研究全面评估了各种再生溶液成分、混合物和操作注意事项对 "可再生 "和 "PFAS 选择性 "AER 的可再生性的影响。对再生剂溶液成分进行批量筛选后发现,这两类树脂都可以通过盐卤水和有机助溶剂的组合进行有效再生,而对于选择性 PFAS 的 AER 来说,高助溶剂比例是必要的。虽然仅使用盐水或仅使用溶剂的再生溶液都不能有效解吸 PFAS,但盐水/共溶剂混合物的再生效果因盐的类型和共溶剂的成分而异。氯化物盐的效果优于硫酸盐和碳酸氢盐,共溶剂的功效取决于所使用的体积分数和类型,而高非极性溶液则可实现最佳的全氟辛烷磺酸解吸效果。连续流再生实验表明,使用 10 个床层体积(BVs)的 70% 甲醇盐水溶液,可再生 AER 几乎能完全解吸 PFAS,而 PFAS 选择性树脂则需要更多床层体积(30)的甲醇含量较高(90%)的盐水或疏水性更强的共溶剂(正丙醇);增加再生剂空床接触时间对 PFAS 解吸的影响微乎其微。此外,利用蒸馏法从产生的废再生剂混合物中回收了 90% 的甲醇,PFAS 污染几乎可以忽略不计,剩下的 PFAS 浓缩蒸馏器底部废料体积极小,可以进一步处理以销毁 PFAS。生命周期分析表明,使用可再生模式的 PFAS 选择性 AER 进行地下水处理,其环境影响和成本均低于使用传统可再生 AER 的系统,处理成本也低于使用一次性 PFAS 选择性树脂的系统。尽管与直觉相反,但这些发现源于以下事实:PFAS 选择性树脂再生时对助溶剂的要求更高,因此再生溶液的内部回收利用率更高,需要进行场外焚烧或处置的残余废液量更低。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Regeneration of conventional and emerging PFAS-selective anion exchange resins used to treat PFAS-contaminated waters

Regeneration of conventional and emerging PFAS-selective anion exchange resins used to treat PFAS-contaminated waters

Anion exchange resins (AERs) have emerged as a promising separation technology to remediate PFAS-contaminated waters due to their improved selectivities and capacities in comparison to legacy activated carbon adsorbents. Presently, site managers choose between AER systems employing resins defined as being ‘regenerable’ with relatively low PFAS selectivity, and PFAS-selective resins that are marketed as ‘single-use’ media intended for disposal upon PFAS breakthrough. However, the potential for these highly-selective adsorbents to be regenerated and/or reused remains poorly characterized. This study presents a comprehensive evaluation of the efficacy of various regenerant solution constituents, mixtures, and operational considerations on the regenerability of both ‘regenerable’ and ‘PFAS-selective’ AERs that were loaded during a pilot treatment study of PFAS-contaminated groundwater. Batch screening of regenerant solution constituents found that both classes of resins may be effectively regenerated using combinations of salt brine and organic cosolvent, with high cosolvent fractions being necessary for PFAS-selective AERs. While neither brine-only nor solvent-only regenerant solutions led to effective PFAS desorption, the efficacy of regeneration with brine/cosolvent mixtures varied with salt type and cosolvent composition. Chloride salts outperformed sulfate and bicarbonate salts, cosolvent efficacy depended on the volume fraction and type used, and highly non-polar solutions led to optimal PFAS desorption. Continuous-flow regeneration experiments showed near-complete PFAS desorption from regenerable AERs using 10 bed volumes (BVs) of 70 % methanolic brine solutions, whereas PFAS-selective resins required more bed volumes (30) of brines with higher methanol content (90 %) or a more hydrophobic cosolvent (n-propanol); increasing regenerant empty-bed contact time had minimal effect on PFAS desorption. > 90 % methanol recovery from the resulting waste regenerant mixtures was accomplished with negligible PFAS contamination using distillation, leaving a minimal volume of a PFAS-concentrated still bottoms waste that may be further treated for PFAS destruction. Life cycle analyses revealed that groundwater treatment using PFAS-selective AERs operated in a regenerable mode have lower environmental impacts and costs than systems using conventional regenerable AERs, and lower treatment costs than systems operated using PFAS-selective resins in a single-use mode. Although counterintuitive, these findings stem from the fact that higher cosolvent requirements for regeneration of PFAS-selective resins lead to greater internal recycling of regenerant solutions and much lower volumes of residual waste still bottoms that require off-site incineration or disposal.

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来源期刊
Separation and Purification Technology
Separation and Purification Technology 工程技术-工程:化工
CiteScore
14.00
自引率
12.80%
发文量
2347
审稿时长
43 days
期刊介绍: Separation and Purification Technology is a premier journal committed to sharing innovative methods for separation and purification in chemical and environmental engineering, encompassing both homogeneous solutions and heterogeneous mixtures. Our scope includes the separation and/or purification of liquids, vapors, and gases, as well as carbon capture and separation techniques. However, it's important to note that methods solely intended for analytical purposes are not within the scope of the journal. Additionally, disciplines such as soil science, polymer science, and metallurgy fall outside the purview of Separation and Purification Technology. Join us in advancing the field of separation and purification methods for sustainable solutions in chemical and environmental engineering.
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