The impact of PAC-loaded polymer membrane thickness on chloroform removal and comparison of solvent and thermal membrane regeneration methods.

IF 2.5 4区 环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL Water Environment Research Pub Date : 2024-07-01 DOI:10.1002/wer.11081
Yizhi Hou, Brooke K Mayer
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Abstract

Powdered activated carbon (PAC) has better adsorption performance than granular activated carbon (GAC) and is widely used in water purification. In most cases, PAC is dosed into water directly, then precipitated as sludge, and landfilled. In this study, PAC was mixed with a polymer and dissolved in dimethylformamide (DMF) solvent to form a PAC-loaded membrane, which was then tested for chloroform removal. The chloroform adsorption capacity of the PAC membrane increased with increasing membrane thickness because of higher carbon loading. However, regardless of membrane thickness, the flux of the PAC membranes was similar since flux resistance predominantly occurred at the top dense polymer surface. This dense surface can be removed by sandpaper polishing, where the adsorption capacity of the polished PAC membranes was 20% higher than the unpolished membranes because of more even distribution of feed water on the polished surface. Removal of the dense surface via polishing increased the flux by 97% to 130%, exceeding the flux of typical household carbon block filters. Using DMF to regenerate the membrane recovered 48% to 66% of the initial adsorption capacity. Thermal regeneration of the exhausted PAC membrane at 250°C was more effective than DMF regeneration (both in terms of cost and performance), with 83% to 94% PAC membrane regeneration efficiency over four regeneration recycles. After four thermal regeneration cycles, flux increased by 300% and the membrane became brittle because of thermal aging of the polymer, indicating that a total of 6 h of regeneration time (equivalent to three cycles in this study) was the limit for effective PAC membrane performance. PRACTITIONER POINTS: Powdered activated carbon was immobilized on a membrane to remove chloroform from water. Thicker membranes increased adsorption capacity but did not impact flux. Flux and capacity increased using polishing to remove the dense polymer surface and more evenly distribute flow across the membrane. Thermal regeneration of the membrane at 250°C was effective for up to three cycles and outperformed solvent-based regeneration. PAC-loaded filters are relevant for applications such as household carbon block filtration.

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PAC 加载聚合物膜厚度对氯仿去除率的影响以及溶剂和热膜再生方法的比较。
粉末活性炭(PAC)比颗粒活性炭(GAC)具有更好的吸附性能,被广泛应用于水净化领域。在大多数情况下,PAC 被直接投加到水中,然后以污泥的形式沉淀并填埋。在本研究中,将 PAC 与聚合物混合,并溶解在二甲基甲酰胺(DMF)溶剂中,形成 PAC 负载膜,然后对其进行氯仿去除测试。由于载碳量增加,PAC 膜的氯仿吸附能力随膜厚度的增加而增加。然而,无论膜的厚度如何,PAC 膜的通量是相似的,因为通量阻力主要发生在顶部致密的聚合物表面。这种致密表面可以通过砂纸抛光去除,抛光后的 PAC 膜的吸附能力比未抛光的膜高 20%,因为进水在抛光表面的分布更均匀。通过抛光去除致密表面后,通量增加了 97% 至 130%,超过了一般家用碳块过滤器的通量。使用 DMF 对膜进行再生,可回收 48% 至 66% 的初始吸附能力。在 250°C 下对耗尽的 PAC 膜进行热再生比 DMF 再生更有效(在成本和性能方面),在四个再生循环中,PAC 膜的再生效率为 83% 至 94%。经过四次热再生循环后,通量增加了 300%,由于聚合物的热老化,膜变得很脆,这表明总共 6 小时的再生时间(相当于本研究中的三次循环)是 PAC 膜有效性能的极限。实践点:将粉末状活性炭固定在膜上以去除水中的氯仿。较厚的膜提高了吸附能力,但对通量没有影响。通过抛光去除致密的聚合物表面,使膜上的流量分布更均匀,从而提高了通量和容量。膜在 250°C 温度下的热再生有效期长达三个周期,性能优于溶剂再生。加载 PAC 的过滤器适用于家用碳块过滤等应用。
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来源期刊
Water Environment Research
Water Environment Research 环境科学-工程:环境
CiteScore
6.30
自引率
0.00%
发文量
138
审稿时长
11 months
期刊介绍: Published since 1928, Water Environment Research (WER) is an international multidisciplinary water resource management journal for the dissemination of fundamental and applied research in all scientific and technical areas related to water quality and resource recovery. WER''s goal is to foster communication and interdisciplinary research between water sciences and related fields such as environmental toxicology, agriculture, public and occupational health, microbiology, and ecology. In addition to original research articles, short communications, case studies, reviews, and perspectives are encouraged.
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