煤化工废水典型NHCs处理技术研究现状及展望
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摘要
简述了目前传统的物理、化学、生物等方法处理煤化工废水中典型含氮杂环化合物(NHCs)的现状,并介绍了一系列新型处理技术:固定化技术、超声波技术、紫外光解法、超临界水氧化法、磁絮凝技术及等离子体技术等,同时对今后处理煤化工废水中典型含氮杂环化合物(NHCs)的技术发展趋势进行了展望﹒
Briefly the present traditional method such as physics,chemistry and biology of the typical nitrogen heterocyclic compounds in coal chemical industry wastewater treatment of the status quo,and it introduces a series of new processing technology:the immobilization technology,ultrasonic technology,UV method,supercritical water oxidation method,magnetic flocculation technology,plasma technology,etc.as well as the future of nitrogen heterocyclic compounds in coal chemical industry wastewater treatment technology development trend is prospected.
Briefly the present traditional method such as physics,chemistry and biology of the typical nitrogen heterocyclic compounds in coal chemical industry wastewater treatment of the status quo,and it introduces a series of new processing technology:the immobilization technology,ultrasonic technology,UV method,supercritical water oxidation method,magnetic flocculation technology,plasma technology,etc.as well as the future of nitrogen heterocyclic compounds in coal chemical industry wastewater treatment technology development trend is prospected.
引文
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[16]徐伟超,吴翠平,张玉秀,等.喹啉降解菌Ochrobactrum sp.的好氧降解特性及其在焦化废水中的生物强化作用[J].环境科学,2017,38(5):2030-2035.
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[18]谢琪琪,刘永军,刘羽,等.PVA-SA活细胞固定化载体性能表征及喹啉生物降解特性[J].水处理技术,2018,44(3):49-51.
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[22]张永明,白琪,杨立辉,等.紫外光解加速喹啉生物降解和矿化的机制[J].徐州工程学院学报:自然科学版,2014,29(4):1-6.
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[24]王慧斌,廖传华,陈海军,等.超临界水氧化技术处理煤化工废水的试验研究[J].现代化工,2016,36(11):154-158.
[25]郭少妮,金若菲,张爱丽,等.燃料灰吸附-再生处理氮杂环化合物废水的性能研究[J].环境工程,2014,32(2):41-44,50.
[26]王建兵,石婷,程俊阳,等.异相Fenton试剂催化氧化-混凝沉淀深度处理焦化废水[J].环境工程学报,2014,8(7):2658-2664.
[27]杨中喆,尤宏,章波,等.微波强化催化湿式H2O2氧化降解喹啉的研究[J].工业水处理,2016,36(12):26-30.
[28]王红涛.等离子体/光催化/微曝气协同处理焦化废水[D].太原:太原理工大学,2014.
[29]叶招莲,汪斌,路娟娟,等.新型无极准分子光源深度处理水相中含N-杂环化合物[J].环境科学,2012,33(3):849-856.
[30]程伟,高保娇,施雪军.功能接枝微粒PSSS/SiO2的制备及其对水介质中含氮杂环农药的吸附特性[J].环境化学,2013,32(3):402-409.
[2]ZHUANG H F,HAN H J,SHAN S D.Treatment of British Gas/Lurgi coal gasification wastewater using a novel integration of heterogeneous Fenton oxidation on coal fly ash/sewage sludge carbon composite and anaerobic biological process[J].Fuel,2016,178:155-162.
[3]GAO L H,WEN H,TIAN Q Z,et al.Influence of surface modification by sulfuric acid on coking coal's adsorption of coking wastewater[J].Water Science&Technology,2017,76(3):555-566.
[4]刘璐.典型煤化工废水中特征污染物的迁移转化及废水毒性削减研究[D].北京:中国科学院大学,2017.
[5]CHEN L,WANG H Y,WEI H G,et al.Carbon monolith with embedded mesopore and nanoparticles as novel adsorbent for water treatment[J].RSC Advances,2015(53):42540-42547.
[6]张培.黏胶基活性炭纤维吸附处理模拟焦化废水的研究[D].广州:华南理工大学,2013.
[7]徐生盼.生物活性炭对含吲哚和吡啶废水的去除研究[J].广州化工,2011,39(12):115-118.
[8]SAITOH T,SHIBATA K,HIRAIDE M.Rapid removal and photodegradation of tetracycline in water by surfactant-assisted coagulation-sedimentation method[J].Journal of Environmental Chemical Engineering,2014,2(3):1852-1858.
[9]袁霄,李杰,李风亭.新型强化铁盐混凝剂对焦化废水深度处理的研究[J].工业水处理,2016,36(10):65-66,71.
[10]陈傲蕾,章丽萍,常风民,等.臭氧高级氧化法降解生化尾水中喹啉[J].环境工程学报,2015,9(12):5795-5800.
[11]王莹.Mn O2/Al2O3催化臭氧微气泡氧化深度处理煤化工废水[D].哈尔滨:哈尔滨工业大学,2017.
[12]ORTEGA-LIéBANA M C,SáNCHEZ-LóPEZ E,HIDALGO-CARRILLO J,et al.A comparative study of photocatalytic degradation of 3-chloropyridine under UV and solar light by homogeneous(photo-Fenton)and heterogeneous(Ti O2)photocatalysis[J].Applied Catalysis B:Environmental,2012,127:316-322.
[13]刘召华,岳秀萍,周爱娟,等.零价铁促进厌氧微生物降解喹啉效能的研究[J].工业水处理,2017,37(11):34-37.
[14]XU P,HAN H J,ZHUANG H F,et al.Anoxic degradation of nitrogenous heterocyclic compounds by activated sludge and their active sites[J].Journal of Environmental Sciences,2015,31(5):221-225.
[15]王洁炜.喹啉在反硝化条件下降解的影响因素研究[D].太原:太原理工大学,2016.
[16]徐伟超,吴翠平,张玉秀,等.喹啉降解菌Ochrobactrum sp.的好氧降解特性及其在焦化废水中的生物强化作用[J].环境科学,2017,38(5):2030-2035.
[17]张玉秀,豆梦楠,朱康兴,等.喹啉降解菌Rhodococcus sp.的降解特性与生物强化作用[J].中国环境科学,2017,37(6):2340-2346.
[18]谢琪琪,刘永军,刘羽,等.PVA-SA活细胞固定化载体性能表征及喹啉生物降解特性[J].水处理技术,2018,44(3):49-51.
[19]陈振飞,卢桂军,李茂静,等.超声波技术降解焦化废水中有机物的研究[J].工业水处理,2011,31(4):39-42.
[20]成睿.超声空代催化预处理焦化废水的研究[D].昆明:昆明理工大学,2014.
[21]贾胜勇.两级MBR工艺处理煤气化废水生化出水的效能研究[D].哈尔滨:哈尔滨工业大学,2016.
[22]张永明,白琪,杨立辉,等.紫外光解加速喹啉生物降解和矿化的机制[J].徐州工程学院学报:自然科学版,2014,29(4):1-6.
[23]刘春明.超临界水氧化技术降解喹啉废水的研究[D].天津:天津大学,2012.
[24]王慧斌,廖传华,陈海军,等.超临界水氧化技术处理煤化工废水的试验研究[J].现代化工,2016,36(11):154-158.
[25]郭少妮,金若菲,张爱丽,等.燃料灰吸附-再生处理氮杂环化合物废水的性能研究[J].环境工程,2014,32(2):41-44,50.
[26]王建兵,石婷,程俊阳,等.异相Fenton试剂催化氧化-混凝沉淀深度处理焦化废水[J].环境工程学报,2014,8(7):2658-2664.
[27]杨中喆,尤宏,章波,等.微波强化催化湿式H2O2氧化降解喹啉的研究[J].工业水处理,2016,36(12):26-30.
[28]王红涛.等离子体/光催化/微曝气协同处理焦化废水[D].太原:太原理工大学,2014.
[29]叶招莲,汪斌,路娟娟,等.新型无极准分子光源深度处理水相中含N-杂环化合物[J].环境科学,2012,33(3):849-856.
[30]程伟,高保娇,施雪军.功能接枝微粒PSSS/SiO2的制备及其对水介质中含氮杂环农药的吸附特性[J].环境化学,2013,32(3):402-409.