Treatment of high salinity wastewater using CWPO process for reuse

Q Chemistry Journal of Advanced Oxidation Technologies Pub Date : 2017-01-11 DOI:10.1515/jaots-2017-0024

Yakun Zhuo, Mei Sheng, Xueke Liang, Guomin Cao

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引用次数: 5

Abstract

Abstract A high salinity wastewater from epoxy resin was treated with the catalytic wet peroxide oxidation (CWPO) process, so that it can be reused as the chlor-alkali process feedstock. Both bench and pilot scale trials were conducted out in this research. The effect of oxidant (hydrogen peroxide) and catalyst (ferrous sulfate) dosages, and their dosing methods, pH value, temperature, and reaction time on TOC removal by the CWPO process were evaluated through bench experiment. The obtained optimal reaction conditions for the CWPO process were as following: H2O2 dosage = 0.735 M, Fe2+ dosage = 0.027 M, temperature = 90ºC, pH = 3.0–3.5, and reaction time = 200 min. Multiple additions of oxidant and catalyst significantly enhanced TOC removal compared to adding the same total dosage in one step. In a pilot trail, 735 moles of H2O2 and 27 moles of Fe2+ were continuously added to a 1000 L wastewater over 3 hours while the pH and temperature of the reaction solution were automatically controlled at 3.3 ± 0.5 and 90 ± 2℃, respectively, the wastewater TOC values were reduced to less than 150 mg/L from 2500–2700 mg/L, which satisfies the influent TOC limit (200 mg/L) of the diaphragm electrolytic cell. In addition, both the iron ion and sulfate ion concentrations in the pilot effluent were less than their influent limits of the diaphragm electrolytic cell, thus the treated wastewater had been successfully applied in a chlor-alkali plant for production chlorine and caustic soda.

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用CWPO工艺处理高盐度废水回用

摘要采用催化湿式过氧化氧化(CWPO)工艺处理高矿化度环氧树脂废水，使其可作为氯碱工艺的原料回用。本研究进行了台架试验和中试试验。通过台架实验考察了氧化剂(过氧化氢)和催化剂(硫酸亚铁)的投加量、投加方式、pH值、温度和反应时间对CWPO工艺去除TOC的影响。得到的最佳反应条件为:H2O2用量= 0.735 M, Fe2+用量= 0.027 M，温度= 90℃，pH = 3.0 ~ 3.5，反应时间= 200 min。与一次添加相同总用量相比，多次添加氧化剂和催化剂显著提高了TOC的去除率。在中试试验中，将735 mol H2O2和27 mol Fe2+添加到1000 L废水中，在3小时内，自动控制反应溶液pH为3.3±0.5℃，温度为90±2℃，将废水TOC值从2500 ~ 2700 mg/L降至150 mg/L以下，满足隔膜电解槽进水TOC限值(200 mg/L)。此外，中试出水的铁离子和硫酸盐离子浓度均低于隔膜电解槽的进水限值，因此处理后的废水已成功应用于氯碱厂生产氯和烧碱。

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来源期刊

Journal of Advanced Oxidation Technologies 化学-物理化学

CiteScore

0.88

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： The Journal of advanced oxidation technologies (AOTs) has been providing an international forum that accepts papers describing basic research and practical applications of these technologies. The Journal has been publishing articles in the form of critical reviews and research papers focused on the science and engineering of AOTs for water, air and soil treatment. Due to the enormous progress in the applications of various chemical and bio-oxidation and reduction processes, the scope of the Journal is now expanded to include submission in these areas so that high quality submission from industry would also be considered for publication. Specifically, the Journal is soliciting submission in the following areas (alphabetical order): -Advanced Oxidation Nanotechnologies -Bio-Oxidation and Reduction Processes -Catalytic Oxidation -Chemical Oxidation and Reduction Processes -Electrochemical Oxidation -Electrohydraulic Discharge, Cavitation & Sonolysis -Electron Beam & Gamma Irradiation -New Photocatalytic Materials and processes -Non-Thermal Plasma -Ozone-based AOTs -Photochemical Degradation Processes -Sub- and Supercritical Water Oxidation -TiO2 Photocatalytic Redox Processes -UV- and Solar Light-based AOTs -Water-Energy (and Food) Nexus of AOTs