膜法处理精对苯二甲酸精制废水
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摘要
采用"沉淀—超滤—反渗透—电去离子"工艺处理精对苯二甲酸精制废水,产水作为生产工艺用水回用于生产系统,考察了各工艺单元的操作条件。实验结果表明,在沉淀时间为4 h、超滤膜截留分子量为1 000且采用错流过滤模式、反渗透运行压力为1.8~2.2 MPa且温度控制在25~30℃、电去离子单元出水电阻率为5 MΩ·cm的操作条件下,最终出水水质优于GB/T 50109—2014《工业用水软化除盐设计规范》中的二级除盐水指标,可回用为生产工艺用水。
The refined wastewater in purified terephthalic acid production was treated by precipitation-ultra-filtrationreverse osmosis-electric deionization process. The effluent was reused as process water in the production system,and the operation conditions of each unit were examined. The experimental results show that under the operation conditions of precipitation time 4 h,intercepting molecular weight of ultra-filtration membrane 1 000,ultra-filtration with cross-flow mode,operation pressure of reverse osmosis 1.8-2.2 MPa,temperature of reverse osmosis 25-30 ℃ and resistivity of effluent from electric deionization unit 5 MΩ·cm,the water quality of the final effluent is better than the second-level desalting index of GB/T 50109-2014,which means the effluent can be reused as the production process water.
The refined wastewater in purified terephthalic acid production was treated by precipitation-ultra-filtrationreverse osmosis-electric deionization process. The effluent was reused as process water in the production system,and the operation conditions of each unit were examined. The experimental results show that under the operation conditions of precipitation time 4 h,intercepting molecular weight of ultra-filtration membrane 1 000,ultra-filtration with cross-flow mode,operation pressure of reverse osmosis 1.8-2.2 MPa,temperature of reverse osmosis 25-30 ℃ and resistivity of effluent from electric deionization unit 5 MΩ·cm,the water quality of the final effluent is better than the second-level desalting index of GB/T 50109-2014,which means the effluent can be reused as the production process water.
引文
[1]聂颖.精对苯二甲酸生产废水处理技术及其进展[J].乙醛醋酸化工,2014(7):8-12.
[2]陈舒雯,徐竟成,李光明,等. PTA生产废水深度处理与再生利用技术的研究进展[J].化学世界,2013(增刊):99-102.
[3]肖海峰. PTA废水处理工艺的再优化探讨[J].聚酯工业,2016,29(6):48-49.
[4]钟非,梁威,李谷,等.应用于膜分离的预处理技术研究进展与展望[J].环境科学与技术,2006,29(6):106-109.
[5]崔小明.精对苯二甲酸生产废水处理技术进展[J].上海化工,2014,39(1):29-34.
[6]中国电力企业联合会.工业用水软化除盐设计规范:GB/T 50109—2014[S]北京:中国标准出版社,2007.
[7]於扣红,冒永生. PTA精制废水处理工艺的优化[J].合成技术及应用,2012,27(2):44-47.
[8]刘正,彭海珠,孙杰,等.石化污水反渗透浓水“零排放”技术[J].化工环保,2012,32(6):535-538.
[9]陈韶辉,刘宗建.高效液相色谱法测定PTA氧化废水中多环芳烃含量[J].合成纤维工业,2016,39(4):78-79.
[10]国家环境保护总局《水和废水监测分析方法》编委会.水和废水监测分析方法[M]. 4版.北京:中国环境科学出版社,2002.
[11]赵鹏.超滤膜的清洗及污染防控[J].化工环保,2018,38(3):333-337.
[2]陈舒雯,徐竟成,李光明,等. PTA生产废水深度处理与再生利用技术的研究进展[J].化学世界,2013(增刊):99-102.
[3]肖海峰. PTA废水处理工艺的再优化探讨[J].聚酯工业,2016,29(6):48-49.
[4]钟非,梁威,李谷,等.应用于膜分离的预处理技术研究进展与展望[J].环境科学与技术,2006,29(6):106-109.
[5]崔小明.精对苯二甲酸生产废水处理技术进展[J].上海化工,2014,39(1):29-34.
[6]中国电力企业联合会.工业用水软化除盐设计规范:GB/T 50109—2014[S]北京:中国标准出版社,2007.
[7]於扣红,冒永生. PTA精制废水处理工艺的优化[J].合成技术及应用,2012,27(2):44-47.
[8]刘正,彭海珠,孙杰,等.石化污水反渗透浓水“零排放”技术[J].化工环保,2012,32(6):535-538.
[9]陈韶辉,刘宗建.高效液相色谱法测定PTA氧化废水中多环芳烃含量[J].合成纤维工业,2016,39(4):78-79.
[10]国家环境保护总局《水和废水监测分析方法》编委会.水和废水监测分析方法[M]. 4版.北京:中国环境科学出版社,2002.
[11]赵鹏.超滤膜的清洗及污染防控[J].化工环保,2018,38(3):333-337.