再生水消毒副产物去除技术研究进展

三卤甲烷、卤乙酸、卤乙腈、三氯硝基甲烷以及N-亚硝基二甲胺是再生水氯/氯胺消毒中主要的消毒副产物,具有较强的毒性和致癌性,严重威胁生态安全及人体健康。目前难以通过改变消毒条件来减少其生成量,而去除其前驱物可有效降低消毒副产物的生成。文章介绍了氧化法、混凝沉淀法、离子交换法以及膜过滤等方法去除消毒副产物前驱物的研究,重点分析了臭氧氧化法去除消毒副产物前驱物的影响因素,对已生成的消毒副产物的去除也进行了简述。     

Degradation of phenol in mists by a non-thermal plasma reactor

A link tooth wheel-cylinder non-thermal plasma reactor was set up to investigate the degradation of phenol in the mists. In addition, the decomposition efficiency of phenol, TOC removal, and byproduct formation were investigated. The stable discharge was achieved in both air and the mist condition. The decomposition efficiency and TOC removal increased with increasing the input power. For the input power of 3.6 W, the phenol decomposition and TOC removal reached 90% and 47%, respectively. Phenol degradation byproducts were identified as small molecular organic acids, including formic acid, acetic acid, and oxalic acid. Their masses in the trapped solutions first increased and then decreased slightly with increasing the input power. Therefore, the biodegradation capacity of the phenol degradation byproducts can be improved.     

Recent advances in the electrochemical oxidation water treatment: Spotlight on byproduct control

• Byproduct formation mechanisms during electrochemical oxidation water treatment. • Control byproduct formation by quenchers. • Process optimization to suppress byproduct formation. Electrochemical oxidation (EO) is a promising technique for decentralized wastewater treatment, owing to its modular design, high efficiency, and ease of automation and transportation. The catalytic destruction of recalcitrant, non-biodegradable pollutants (per- and poly-fluoroalkyl substances (PFAS), pharmaceuticals, and personal care products (PPCPs), pesticides, etc.) is an appropriate niche for EO. EO can be more effective than homogeneous advanced oxidation processes for the degradation of recalcitrant chemicals inert to radical-mediated oxidation, because the potential of the anode can be made much higher than that of hydroxyl radicals (E_OH = 2.7 V vs. NHE), forcing the direct transfer of electrons from pollutants to electrodes. Unfortunately, at such high anodic potential, chloride ions, which are ubiquitous in natural water systems, will be readily oxidized to chlorine and perchlorate. Perchlorate is a to-be-regulated byproduct, and chlorine can react with matrix organics to produce organic halogen compounds. In the past ten years, novel electrode materials and processes have been developed. However, spotlights were rarely focused on the control of byproduct formation during EO processes in a real-world context. When we use EO techniques to eliminate target contaminants with concentrations at μg/L-levels, byproducts at mg/L-levels might be produced. Is it a good trade-off? Is it possible to inhibit byproduct formation without compromising the performance of EO? In this mini-review, we will summarize the recent advances and provide perspectives to address the above questions.     

新型复合预氧化技术控制副产物的试验研究

臭氧被广泛应用于饮用水预氧化工艺中,但是成本较高,而且会生成臭氧化副产物,如可同化有机碳(AOC)、溴酸盐和甲醛.因此,提出臭氧/高锰酸钾复合预氧化技术,并对照预臭氧化技术,进行了消毒副产物前质及臭氧化副产物控制的小试试验研究.结果表明,与预臭氧化(1.5 mg/L臭氧)相比,复合预氧化(0.6 mg/L臭氧 0.4 mg/L高锰酸钾)能促进混凝沉淀对消毒副产物前质的去除,总去除率与单独预臭氧化的去除率相当.而且又能降低AOC生成量,并促进混凝沉淀对AOC的去除,合计AOC去除率达43%左右.此外,对溴酸盐和甲醛生成量也有明显去除效果,比单独预臭氧化降低了78.4%和21.2%.