湿法冶金

参考文献

[1] 于艳杰,吴莹,方登志,等.曝气微电解混凝沉淀处理含砷铬废水[J].工业水处理,2018,38(2):82-84.

[2] 高小娟,王璠,汪启年.含砷废水处理研究进展[J].工业水处理,2012,32(2):10-15.

[3] 刘雅文.砷污染防治:还一片碧水净土[J].化工管理,2014(10):51-53.

[4] 庄明龙,柴立元,闵小波,等.含砷废水处理研究进展[J].工业水处理,2004,24(7):13-17.

[5] 来进贤,金明虎.铁盐沉淀—絮凝法处理矿山低浓度含砷废水[J].化工环保,2018,38(3):328-332.

[6] 张帆,龙晓波,邱邻霖,等.连续沉淀法处理酸性含砷废水[J].昆明冶金高等专科学校学报,2018,34(3):92-97.

[7] 屈娜.贵冶硫化中和法除砷工艺探讨[J].铜业工程,2009(2):16-19.

[8] 王艳,王曙光,郑赛,等.改性活性炭吸附除砷的研究[J].应用化工,2014,43(1):63-65.

[9] 曹金艳.离子液体负载型碳纳米管吸附材料制备及吸附除砷研究[D].长沙:中南大学,2008.

[10] 付小琳.Fe3O4-MnO2纳米材料吸附除砷(Ⅲ)及磁性分离方法研究[D].哈尔滨:哈尔滨工业大学,2015.

[11] 潘尹银,徐双,刘晨明,等.吸附法去除钨冶炼废水中的砷[J].化工环保,2018,38(2):196-201.

[12] PALMER C D,PULS ROBERT W.Natural attenuation of hexavalent chromium in groundwater and soils,EPA/540/5-94/505[R].Washington:Environmental Protection Agency Press,1994.

[13] 成婉玲.焦亚硫酸钠处理混有氰化物的含铬废水的原理探讨[J].广东化工,2013,40(10):122-123.

[14] 李健军.用焦亚硫酸钠处理废水中铬[J].理化检验(化学分册),2005,41(3):213.

[15] 陈立丰.活性炭对电镀废水中Cr6+的吸附:活性炭选择吸附的热力学和动力学方法[J].水处理技术,1992,18(3):205-210.

[16] 方金鹏.复合吸附剂吸附水中六价铬的研究[D].长沙:湖南大学,2008.

[17] 黄美苓.多孔碳复合材料的制备及吸附六价铬的研究[D].济南:济南大学,2017.

[18] 何忠明,王琼,付宏渊,等.柚子皮吸附去除水中的六价铬和砷[J].环境工程,2016,34(增刊1):299-302.

[19] 王传岭,于敏,蓝裕青.AlCl3改性柚子皮吸附去除水中的铬离子[J].山东化工,2018,47(16):188-191.

[20] TANG C,HUANG Y H,ZENG H,et al.Reductive removal of selenate by zero-valent iron:the roles of aqueous Fe2+ and corrosion products and selenate removal mechanisms[J].Water Research,2014,67:166-174.

[21] MURPHY A P.Removal of selenate from water by chemical reduction[J].Industrial & Engineering Chemistry Research,1988,27(1):187-191.

[22] MONDAL K,JEGADEESAN G,LALVANI S B.Removal of selenate by Fe and NiFe nanosized particles[J].Industrial & Engineering Chemistry Research,2004,43(16):4922-4934.

[23] ZHAO J X,MATSUNE H,TAKENAKA S,et al.Reduction of selenate with hydrazine monohydrate over Pt catalysts in aqueous solution[J].Chemical Engineering Journal,2017,308(9):963-973.

[24] 潘丙才,单超,王兴.一种去除水中六价硒的组合工艺:CN108558086A[P].2018-09-21.

[25] ZHANG Y Q,WANG J F,AMRHEIN C,et al.Removal of selenate from water by zero-valent iron[J].Journal of Environment Quality,2005,34(2):487-495.

[26] GUAN X,SUN Y,QIN H,et al.The limitations of applying zero-valent iron technology in contaminants sequestration and the corresponding countermeasures:the development in zero-valent iron technology in the last two decades(1994—2014)[J].Water Research,2015,75(10):224-248.

[27] NOUBACTEP C.Metallic iron for environmental remediation:the long walk to evidence[J].Corrosion Reviews,2013,31(2):51-59.

[28] AGRAWAL A,TRATNYEK P G.Reduction of nitro aromatic compounds by zerovalent iron metal[J].Environmental Science Technology,1996,30(1):153-160.

[29] GEIGER C L,RUIZ N E,CLAUSEN C A,et al.Ultrasound pretreatment of elemental iron:kinetic studies of dehalogenation reaction enhancement and surface effects[J].Water Research,2002,36(5):1342-1350.

[30] SHAN C,CHEN J J,YANG Z,et al.Enhanced removal of Se(Ⅵ) from water via pre-corrosion of zerovalent iron using H2O2/HCl:effect of solution chemistry and mechanism investigation[J].Water Research,2018,133(7):173-181.

[31] 潘丙才,单超,杨喆,等.一种悬浊液态含铁复合试剂及其制备方法和高效去除水中硒酸盐的方法:CN106365244A[P].2017-02-01.

[32] SHAN C,WANG X,GUAN X H,et al.Efficient removal of trace Se(Ⅵ) by millimeter-sized nanocomposite of zerovalent from iron confined in polymeric anion exchanger[J].Industrial & Engineering Chemistry Research,2017,56:5309-5317.

[33] 李鹏.含铅废水的危害及其处理工艺的研究[J].水污染及处理,2018,6(1):38-46.

[34] 何绪文,胡建龙,李静文,等.硫化物沉淀法处理含铅废水[J].环境工程学报,2013,7(4):1394-1398.

[35] SALAZAR-RABAGO J J,LEYVA-RAMOS R.Novel biosorbent with high adsorption capacity prepared by chemical modification of white pine(Pinus durangensis) sawdust.Adsorption of Pb(Ⅱ) from aqueous solutions [J].Journal of Environmental Management,2016,169(3):303-312.

[36] ESMAEILI A,KALANTARI M,SAREMNIA B.Biosorption of Pb(Ⅱ) from aqueous solutions by modified of two kinds of marine algae,sargassum glaucescens and gracilaria corticata[J].Polish Journal of Chemical Technology,2012,14(2):22-28.

[37] KARTHIK R,MEENAKSHI S.Chemical modification of chitin with polypyrrole for the uptake of Pb(Ⅱ) and Cd(Ⅱ) ions[J].International Journal of Biological Macromolecules,2015,78(6):157-164.

[38] 杨富新.中和法处理酸性含铜、锌离子污水的pH控制[J].冶金丛刊,1995,18(4):30-31.

[39] 中国国家环保局.污水综合排放标准:GB 8978—1996[S].北京:中国环境科学出版社,1997.

[40] 高翔.有机硅废水中铜锌离子的自凝聚研究[D].南昌:南昌航空大学,2014.

[41] 何闪英,陈昆柏.电混凝法处理电镀废水中的Cu2+和Zn2+[J].能源工程,2009,29(1):43-47.

[42] 袁晓乐,张广山,李硕,等.络合萃取法处理高浓度含铜废水[J].现代化工,2019,39(1):85-88.

[43] 文震林,沈文豪,余佳平.泡沫浮选萃取分离回收废水中铜锌[J].上海大学学报(自然科学版),2006,29(3):320-324.

[44] 王海棠.高浓度酸性铜锌废水分步硫化处理研究[D].长沙:中南大学,2013.

[45] 张斐,赵静.酸性重金属废水处理工艺[J].化学工程与装备,2018(8):324-326.

[46] 赵慧.络合—超滤耦合工艺深度处理有色金属矿山重金属废水技术研究[D].邯郸:河北工程大学,2014.

[47] 谭聪.重金属捕集剂DTC-SC的制备及其应用研究[D].南宁:广西大学,2015.