高盐废水单质分盐与资源化利用的研究进展

doi:10.11962/1006-4990.2018-0618

Abstract

Abstract:

High salinity wastewater generated in industrial production is a kind of wastewater that is difficult to be treated. Direct discharge or improper management will lead to the pollution of environment and cause waste of resources.Therefore,economic and efficient treatment technology should be adopted to treat and reuse it.Combined with the background of the treatment of high salinity wastewater,the common treatment technology of industrial high salinity wastewater and the salt separation process were introduced.The advantages and disadvantages of these common techniques were analyzed combined with engineering and invention example.Finally,it proposed that solving the defects in the current combined salt separation process and optimizing the existing process would become an important research direction for the future industrial high salinity wastewater treatment.

Key words: high salinity wastewater, salt separation, resource utilization

CLC Number:

TQ124.4

Bian Xiaotong,Huang Yongming,Guo Rutao,Xu Donghua,Zhu Liangbing,Yang Ji,Qiu Zhaofu. Research progress on salt separation and resource utilization in high salinity wastewater[J]. Inorganic Chemicals Industry, 2019, 51(8): 7-12.

References 57

[1]	陈浩, 张枫, 王中正 , 等. 高盐废水处理技术研究进展[J]. 广州化工, 2017,45(19):13-15.
[2]	陈明燕, 蓝大蔚, 刘宇程 . 高含盐废水脱盐处理技术研究进展[J]. 化工环保, 2018,38(1):19-24.
[3]	李玲密, 宋宝华, 王中原 , 等. 高含盐工业废水蒸发结晶探讨[J]. 环境工程, 2014,32(s1):202-205.
[4]	李凤娟, 徐菲, 李小龙 , 等. 高盐度废水处理技术研究进展[J]. 环境科学与管理, 2014,39(2):72-75.
[5]	乌云, 杨鲁伟, 张振涛 , 等. 高含盐有机废水蒸发浓缩分离特性实验研究[J]. 环境工程, 2015,33(8):8-12.
[6]	李柄缘, 刘光全, 王莹 , 等. 高盐废水的形成及其处理技术进展[J]. 化工进展, 2014,33(2):493-497,515.
[7]	田颖, 滕济林, 李若征 , 等. 煤化工杂盐脱除有机物回收无机盐的实验研究[J]. 化学工程, 2018,46(6):68-72.
[8]	周厚方, 施武斌, 丁志刚 , 等. 煤化工高浓盐水分质资源化利用[J]. 煤炭加工与综合利用, 2017(12):23-26.
[9]	王江波, 时历杰, 汪根存 , 等. 煤化工高浓盐水资源化利用新工艺研究[J]. 无机盐工业, 2018,50(7):54-58.
[10]	王鉴, 郭天娇, 丰铭 , 等. 高含盐工业废水处理技术现状及研究进展[J]. 煤化工, 2015,43(3):18-21.
[11]	李琨, 徐春艳, 韩洪军 , 等. 煤化工浓盐水热膜耦合工业盐资源化利用研究[J]. 给水排水, 2018,54(1):70-75.
[12]	宋岱峰, 许锦鹏 . 新型“膜法&蒸发“浓水零排放处理技术——SUPER RO特种膜[C] //中国化学制药工业协会,国药励展公司.首届中国国际制药工业环保发展论坛.成都, 2014: 75-80.
[13]	靳辉, 朱海霖, 郭玉海 , 等. 多效膜蒸馏技术处理电镀废水反渗透浓水的研究[J]. 浙江理工大学学报:自然科学版, 2016,35(4):528-532.
[14]	武春瑞, 赵鹏, 赵晶 , 等. 反渗透浓水膜蒸馏法处理过程[C] //中国化工学会.第二届全国石油和化工行业节能节水技术论坛论文汇编.南京, 2007: 410-411.
[15]	秦英杰, 王焕, 刘立强 , 等. 经反渗透处理后炼油废水浓水的多效膜蒸馏技术[C] //中国化工学会.2011年年会暨第四届全国石油和化工行业节能节水减排技术论坛论文集.郑州, 2011: 844-848.
[16]	程方琳, 刘宇坚, 胡永健 , 等. 膜蒸馏技术处理RO浓水的研究现状与进展[J]. 广东化工, 2016,43(21):104-106.
[17]	张金鸿, 侯霙, 李海芳 , 等. 机械蒸汽再压缩技术处理反渗透浓水的中试研究[J]. 中国给水排水, 2011,27(11):1-4.
[18]	崔凤霞, 李荣, 陈玮娜 . 高含盐废水零排放蒸发结晶技术进展[J]. 广州化工, 2017,45(1):21-23.
[19]	张绍坤 . 三效蒸发器在高含盐废水处理中的应用[J]. 中国环保产业, 2011(11):37-40.
[20]	周庆阔 . 三效蒸发技术处理高浓度废水[J]. 中国化工贸易, 2017,9(5):102-103.
[21]	陈玉兵 . 三效并流蒸发用于高含盐化工废水处理工程[J]. 给水排水, 2015,51(1):54-55.
[22]	Zhao Dongfeng, Xue Jianliang, Li Shi , et al. Theoretical analyses of thermal and economical aspects of multi-effect distillation desali-nation dealing with high-salinity wastewater[J]. Desalination, 2011,273(2/3):292-298.
[23]	王一鸣 . 二次蒸汽再压缩蒸发过程分析及工程应用[J]. 广州化工, 2015(10):148-150.
[24]	王彦飞, 杨静, 王婧莹 , 等. 煤化工高浓盐废水蒸发处理工艺进展[J]. 无机盐工业, 2017,49(1):10-14.
[25]	王海, 张峰榛, 王成端 , 等. MVR技术处理高盐废水工艺的模拟与分析[J]. 环境工程, 2015,33(10):35-37.
[26]	周海云, 姜伟立, 徐晨 , 等. 机械蒸汽再压缩技术处理阿斯巴甜生产废水的研究[J]. 工业水处理, 2017,37(9):60-63.
[27]	余海晨, 钟沛文, 高玮 , 等. 合成化工高盐废水的零排放工艺设计及研究[J]. 城市环境与城市生态, 2013,26(1):44-46.
[28]	Al-Sahali M, Ettouney H . Developments in thermal desalination processes:Design,energy,and costing aspects[J]. Desalination, 2007,214(1):227-240.
[29]	Al-Obaidani S, Curcio E, Macedonio F , et al. Potential of mem-brane distillation in seawater desalination:Thermal efficiency,sensitivity study and cost estimation[J]. Journal of Membrane Science, 2008,323(1):85-98.
[30]	张新妙, 王玉杰, 彭海珠 . 膜蒸馏处理石化高盐废水技术研究[J]. 现代化工, 2015,35(1):153-157,159.
[31]	李福勤, 吕晓龙, 唐玮媛 , 等. 高盐废水制取高纯水工艺研究[J]. 水处理技术, 2013,39(9):109-111.
[32]	Alklaibi A M, Lior N . Membrane-distillation desalination:Status and potential[J]. Desalination, 2005,171(2):111-131. doi: 10.1016/j.desal.2004.03.024
[33]	Reid E, Liu X, Judd S J . Effect of high salinity on activated sludge characteristics and membrane permeability in an immersed mem-brane bioreactor[J]. Journal of Membrane Science, 2006,283(1):164-171. doi: 10.1016/j.memsci.2006.06.021
[34]	Kargi F, Dinçer A R . Saline wastewater treatment by halophile-sup-plemented activated sludge culture in an aerated rotating biodisc contactor[J]. Enzyme & Microbial Technology, 1998,22(6):427-433.
[35]	刘正 . 高浓度含盐废水生物处理技术[J]. 化工环保, 2004,24(s1):209-211.
[36]	吕宝一, 谢冰, 邵春利 , 等. 两段A/O生物接触氧化法处理高盐有机废水研究[J]. 中国给水排水, 2011,27(1):102-104,108.
[37]	周健, 吴绮桃, 龙腾锐 , 等. 高盐榨菜腌制废水处理的微生物系统构建研究[J]. 中国给水排水, 2007,23(15):17-20,25.
[38]	王爱芳, 鲍建国 . 高盐废水生物处理的研究现状[J]. 环境科学与技术, 2009,32(b06):209-213.
[39]	曹芳利 . 高盐废水分盐结晶工艺技术[J]. 商品与质量, 2017(10):280.
[40]	左武, 葛仕福, 朱化军 , 等. 高含盐有机废液热处理技术研究进展[J]. 环境工程, 2018,36(4):47-51.
[41]	李昆, 王健行, 魏源送 . 纳滤在水处理与回用中的应用现状与展望[J]. 环境科学学报, 2016,36(8):2714-2729.
[42]	Mohammad A W, Teow Y H, Ang W L , et al. Nanofiltration mem-branes review:Recent advances and future prospects[J]. Desalination, 2015,356:226-254. doi: 10.1016/j.desal.2014.10.043
[43]	徐成燕, 俞彬, 王小军 , 等. 催化废水零排放及分盐中试研究[J]. 工业水处理, 2018,38(5):39-41.
[44]	赛世杰 . 纳滤膜在高盐废水零排放领域的分盐性能研究[J]. 工业水处理, 2017,37(9):75-78.
[45]	郭驭, 王小 . 纳滤膜污染机理、表征及控制[J]. 给水排水, 2017,53(9):120-131.
[46]	郝红勋, 卢海娇, 苏楠楠 , 等. 从高盐废水中提取可资源化利用的高纯度硫酸钠和氯化钠的分质结晶方法:中国, 107867707A[P]. 2017-10-23.
[47]	郑阳, 党平, 李买军 , 等. 煤化工高含盐废水“分质盐零排放”处理技术研究进展[C] //中国环境科学学会.2017年中国环境科学学会科学与技术年会.厦门, 2017: 2769-2772.
[48]	张继军 . 一种高盐废水的回收处理方法:中国, 105036222A[P]. 2015-08-19.
[49]	赛世杰, 党平, 刘慧 , 等. 煤化工高盐废水分质盐零排放技术的运行效果研究[J]. 煤炭加工与综合利用, 2017(4):52-55.
[50]	何睦盈, 张亚峰 . 冷冻脱硝-纳滤-热泵蒸发技术处理高盐废水[J]. 给水排水, 2013,49(11):60-63.
[51]	张琳, 蒋枫, 魏雅宁 , 等. 纳滤膜法处理阿斯巴甜高含盐有机废水试验[J]. 农业工程学报, 2015,31(s1):276-283.
[52]	邢明皓 . 一种提取煤化工高含盐废水中高纯度硫酸钠及氯化钠产品的方法:中国, 106116002A[P]. 2016-08-03.
[53]	区瑞锟, 姜广义 . 一种含氯化钠与硫酸钠的高盐废水资源化处理装置:中国, 205676303U[P]. 2016-04-21.
[54]	吴雅琴, 申屠勋玉, 杨波 , 等. 膜集成技术在煤化工高盐废水资源化中的应用[J]. 煤化工, 2016,44(4):6-9.
[55]	韩萌 . 采用联合制碱法资源化利用高盐废水工艺研究[D]. 北京:北京化工大学, 2017.
[56]	周国娥, 钟红梅, 梁美东 . 水合肼副产盐渣制小苏打新工艺研究[J]. 无机盐工业, 2017,49(6):53-55.
[57]	方映春 . 高浓高盐化工废水的资源化综合处理工艺[J]. 化工设计通讯, 2016,42(9):47-48.

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Research progress on salt separation and resource utilization in high salinity wastewater

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