Degradation mechanism of 2,4,6-trinitrotoluene in supercritical water oxidation 被引量：15

Degradation mechanism of 2,4,6-trinitrotoluene in supercritical water oxidation

下载PDF

导出

摘要 The 2,4,6-trinitrotoluene （TNT） is a potential carcinogens and TNT contaminated wastewater, which could not be effectively disposed with conventional treatments. The supercritical water oxidation （SCWO） to treat TNT contaminated wastewater was studied in this article, The TNT concentration in wastewater was measured by high-performance liquid chromatograph （HPLC） and the degraded intermediates were analyzed using GC-MS. The results showed that SCWO could degrade TNT efficiently in the presence of oxygen. The reaction temperature, pressure, residence time and oxygen excess were the main contributing factors in the process. The decomposition of TNT was accelerated as the temperature or residence time increased. At 550℃, 24 MPa, 120 s and oxygen excess 300%, TNT removal rate could exceed 99.9%. Partial oxidation occured in SCWO without oxygen. It was concluded that supercritical water was a good solvent and had excellent oxidation capability in the existence of oxygen. The main intermediates of TNT during SCWO included toluene, 1,3,5-trinitrobenzene, nitrophenol, naphthalene, fluorenone, dibutyl phthalate, alkanes and several dimers based on the intermediate analysis. Some side reactions, such as coupled reaction, hydrolysis reaction and isomerization reaction may take place simultaneously when TNT was oxidized by SCWO. The 2,4,6-trinitrotoluene （TNT） is a potential carcinogens and TNT contaminated wastewater, which could not be effectively disposed with conventional treatments. The supercritical water oxidation （SCWO） to treat TNT contaminated wastewater was studied in this article, The TNT concentration in wastewater was measured by high-performance liquid chromatograph （HPLC） and the degraded intermediates were analyzed using GC-MS. The results showed that SCWO could degrade TNT efficiently in the presence of oxygen. The reaction temperature, pressure, residence time and oxygen excess were the main contributing factors in the process. The decomposition of TNT was accelerated as the temperature or residence time increased. At 550℃, 24 MPa, 120 s and oxygen excess 300%, TNT removal rate could exceed 99.9%. Partial oxidation occured in SCWO without oxygen. It was concluded that supercritical water was a good solvent and had excellent oxidation capability in the existence of oxygen. The main intermediates of TNT during SCWO included toluene, 1,3,5-trinitrobenzene, nitrophenol, naphthalene, fluorenone, dibutyl phthalate, alkanes and several dimers based on the intermediate analysis. Some side reactions, such as coupled reaction, hydrolysis reaction and isomerization reaction may take place simultaneously when TNT was oxidized by SCWO.

作者 CHANG Shuang-jun LIU Yu-cun

机构地区 College of Chemical Engineering and Environment

出处《Journal of Environmental Sciences》 SCIE EI CAS CSCD 2007年第12期1430-1435,共6页 环境科学学报（英文版）

基金 Project supported by the Science Technology Foundation of Educational Department(No.204020).

关键词 supercritical water oxidation TNT degradation mechanism wastewater treatment supercritical water oxidation TNT degradation mechanism wastewater treatment

分类号 X703 [环境科学与工程—环境工程]

引文网络
相关文献

参考文献17

1DiNaro J L, Tester J W, Howard J B, 2000. Experimental measurements of benzene oxidation in supercritical water[J]. Reactors, Kinetics, and Catalysis, 46(11): 2274-2283. 被引量：1
2Gopalan S, Savage P E, 1994. Reaction mechanism for phenol oxidation in supercritical water[J]. Phys Chem, 98: 12646- 12652. 被引量：1
3Gopalan S, Savage P E, 1995. A reaction network model for phenol oxidation in supercritical water [J]. AIChE J, 41: 1864-1873. 被引量：1
4Killilea W R, Swallow K C, Hong G T, 1992. The fate of nitrogen in supercritical water oxidation[J]. Supercritical Fluids, 5: 72-78. 被引量：1
5Li Z M, Comfort S D, Shea P J, 1997. Destruction of 2,4,6- trinitrotoluene by Fenton oxidation[J]. Environ Qual, 26: 480-487. 被引量：1
6Liou M J, Lu M C, Chen J N, 2004. Oxidation of TNT by photo- Fenton process[J]. Chemosphere, 57: 1107-1114. 被引量：1
7Magdalena S, Morgan F, Michael M, 2004. Environmental assessment of supercritical water oxidation of sewage sludge[J]. Resources, Conservation and Recycling, 41: 321-338. 被引量：1
8March J, 1985. Advance organic chemistry[M]. Third ed. Canada: Wiley. 786. 被引量：1
9Modell M, 1987. Detoxification and disposal of hazardous organic chemicals by processing in supercritical water[R]. Final report. Contract number DAMD 17-80-C-0078. 被引量：1
10Nijs J D, Frank M, 2002. Assessment of technologies for disposing explosive waste[J]. Hazardous Materials, A90: 137-153. 被引量：1

二级参考文献28

1LI Z M,Shea P J,Comfort S D. Fenton oxidation of 2,4,6-trinitrotoluene in contaminated soil slurries [ J ]. Environmental Engineering Science, 1997,14( 1 ) : 55 - 66. 被引量：1
2Bin A K,Machniewski, Sakowicz P, et al. Degradation of nitroaromatics (MINT, DNT and TNT) by AOPs, Ozone[J]. Science and Engineering,2001,23(5) : 343 -349. 被引量：1
3Bier E L,Singh J,LI Z M,et al. Remediating hexahydro-1,3,5-trinitro-1,2,5-trazine-contaminated water and soil by Fenton oxidation [ J ]. Environmental Toxicology and Chemistry,1999,18 (6) : 1078 - 1084. 被引量：1
4Zoh K D, Stenstrom M K. Fenton oxidation of hexahydro-1,3,5-trlnitro-1,3,5-triazine (RDX) and oetahydro-1,3,5,7-tetranitro-1,3,5,7-tetrazocine (HMX) [ J ]. Water Reaoareh,2002,36(5) : 1331 - 1341. 被引量：1
5Burrows W D,Brueggemann E E. Tertiary treatment of effluent from Hdston AAP indutrial liauid waste treatment fadlity[R]. V. NTIS No AP-A176195/6/FIDM,Sep,1986. 被引量：1
6Bose P,Gaze W H, Massox D S. Degradation of RDX by various advanced oxidation processes: I. Reaction rates[J]. Water Res. ,1998,32(4) : 997 - 1004. 被引量：1
7Bose P ,Gaze W H,Massox D S. Degradation of RDX by various advanced oxidation processes: Ⅱ. Organic by-products[J]. Water Res. ,1998,32(4) : 1005 - 1018. 被引量：1
8Andrews Catherine C. Photooxide treatment of TNT contaminated waste water[R]. AD-AO,84684,1980. 被引量：1
9Glaze W H. Ozone and advanced oxidation processes for water treatment[J/OL]. http ://www. sph. une. edu/en-vr/publieations/esenotes/falDS/enfallg5, htm. 被引量：1
10Himebaugh W S. Advanced oxidation of munitions in wastewater[ J ]. National Environmental Journal, 1995,5(6) : 42 -45. 被引量：1

共引文献33

1于娜娜,陈东方,寸冬梅,陈珍.炸药废水处理最新技术进展[J].化工中间体,2011,7(9):9-11.
2张洪玲,蔡金傍.含硝基芳香族化合物废水处理技术研究进展[J].环境科学与技术,2011,34(S2):113-117. 被引量：8
3苏俊霞,刘玉存,柴涛.TNT炸药废水处理技术的研究现状[J].科技情报开发与经济,2005,15(1):122-124. 被引量：16
4吴耀国,赵晨辉,惠林,赵大为.废水溶液化学组分对O_3/H_2O_2氧化TNT功效的影响[J].含能材料,2004,12(6):353-357.
5郭峰波.UV/Fenton试剂处理DDNP废水研究[J].火工品,2006(5):21-23. 被引量：5
6袁凤英,秦清风.UV助Fenton高级氧化技术处理黑索今废水研究[J].中北大学学报（自然科学版）,2006,27(6):511-514. 被引量：7
7常双君,刘玉存.炸药废水的绿色化处理工艺研究(英文)[J].中山大学学报（自然科学版）,2007,46(B06):82-83. 被引量：1
8刘作华,周小霞,杜军,刘仁龙,陶长元.强化Fenton法降解含能材料废水的研究(英文)[J].含能材料,2007,15(6):670-675.
9尹娟娟,袁凤英,宋伟,姚红云.光助Fenton试剂处理HMX炸药废水研究[J].火工品,2008(2):20-23. 被引量：6
10陈海燕,施耀,雷乐成,张晔,褚海林,杨睿戆.催化协同高压脉冲气相放电降解TNT废水[J].水处理技术,2008,34(7):39-42. 被引量：4

同被引文献199

1周明华,戴启洲,雷乐成,吴祖成,马淳安,汪大.新型二氧化铅阳极电催化降解有机污染物的特性研究[J].物理化学学报,2004,20(8):871-876. 被引量：61
2吴耀国,赵大为,赵晨辉,惠林.TNT的O_3/H_2O_2降解规律[J].火炸药学报,2004,27(3):42-45. 被引量：13
3徐涛,肖贤明,刘红英.UV/H_2O_2光化降解水中邻二氯苯的反应机理[J].中国环境科学,2004,24(5):547-551. 被引量：17
4杨丽君,蒋文举.磷酸微波法制污水污泥活性炭的研究[J].中国资源综合利用,2004(12):15-18. 被引量：21
5朱永安.活性炭吸附法处理含苯胺、硝基苯废水的实验研究[J].沈阳化工,1993,22(3):44-47. 被引量：10
6严晔楠,李素芹,苍大强.冶金行业节水新技术和建议[J].中国冶金,2005,15(2):37-40. 被引量：2
7吴耀国,赵大为,赵晨辉,惠林,王秋华.O_3、O_3/H_2O_2降解TNT的实验研究[J].西北工业大学学报,2005,23(1):129-133. 被引量：7
8高松,周增炎,高廷耀.自组生物动态膜在污泥截留中的应用研究[J].净水技术,2005,24(1):14-17. 被引量：22
9范广裕.污染防治技术含TNT、TNBA、DPA废水的处理研究[J].环境保护,1995,23(4):9-12. 被引量：8
10王亮,王树众,张钦明,赵威,林宗虎.超临界水氧化处理含油废水的实验研究[J].环境污染与防治,2005,27(7):546-549. 被引量：34

引证文献15

1刘杨先,王燕.UV/H_2O_2高级氧化工艺在化工与环保领域的研究进展[J].化学工业与工程技术,2010,31(3):33-38. 被引量：4
2乔小晶,暴丽霞.炸药废水处理的研究进展[J].安全与环境学报,2010,10(5):32-38. 被引量：5
3刘杨先,张军.UV/H_2O_2高级氧化工艺反应机理与影响因素最新研究进展[J].化学工业与工程技术,2011,32(3):18-24. 被引量：9
4徐志红,高云虎,王涛,费维扬.超临界水氧化技术处理难降解有机物的研究进展[J].现代化工,2013,33(6):19-22. 被引量：8
5付丹,张以河.TNT废水处理技术研究进展[J].能源环境保护,2014,28(2):5-8. 被引量：4
6蒋国民,魏静,晁成,孙东平,杨加志.细菌纤维素负载TiO_2用于DDNP废水光催化降解研究[J].功能材料,2015,46(2):2023-2027. 被引量：6
7曹娟,于静,陈婷婷,金佳奇.动态生物膜—电化学耦合处理炸药废水的研究[J].环境保护与循环经济,2015,35(1):34-37. 被引量：1
8付丹.化学法处理硝基苯类废水研究进展[J].四川化工,2015,18(1):21-23.
9钱江枰,杜静.火炸药废水处理方法综述[J].浙江化工,2015,46(6):51-54. 被引量：4
10彭利冲,李素芹,郭丽婷.超临界水氧化轧钢含油污泥减量无害化处理[J].中国冶金,2017,27(5):75-80. 被引量：10

二级引证文献62

1宋晓抗,王四芳.超临界水氧化处理有机危废工业化应用进展[J].一重技术,2019,0(6):50-54. 被引量：3
2刘杨先,张军,王助良.UV/H_2O_2氧化联合Ca(OH)_2吸收同时脱硫脱硝[J].化工学报,2012,63(10):3277-3283. 被引量：15
3蔡邦宏,张姗姗,董筠,曾雯,何江.UV/H_2O_2处理丽华实红玉染料溶液[J].兰州理工大学学报,2012,38(5):62-65.
4王铮,张静萱,李润青,郝雯.超声-光化学氧化法处理精制棉废水[J].火炸药学报,2013,36(2):76-81. 被引量：8
5尚海茹,刘霞,冯长根.TNT、RDX及HMX炸药废水处理技术综述[J].安全与环境学报,2013,13(6):9-14. 被引量：5
6聂冬,金明姬,董微巍,周善英.高级氧化法在水处理领域中的应用研究[J].延边大学农学学报,2014,36(2):179-185. 被引量：26
7雷英春,王永涛,王晶禹,李保军,薛水平,任慧.TATB炸药废水序批式生物处理工艺研究[J].安全与环境学报,2014,14(6):169-173. 被引量：1
8蒋云芸.超临界CO_2技术处理火炸药废水的优势及前景[J].广州化工,2015,43(10):36-38.
9刘欣伟,陈勇,陈超,陈昌兵,张文通.TiO_2光催化材料在TNT弹药废水处理中的应用研究进展[J].材料导报（纳米与新材料专辑）,2015,29(2):428-432. 被引量：4
10陆剑平,陈文如,王建峰,任举,温建华,司双喜.牛磺酸生产中含硫酸铵高盐废水的综合处理[J].山东化工,2016,45(12):181-183. 被引量：1

1杜艳芬,韩卿,张荣莉.超临界水氧化法处理废水[J].西南造纸,2001,30(4):13-14. 被引量：9
2王俊江.一曝建立碳化—硝化联合反应可行性分析[J].胜炼科技,1997,19(2):10-13.
3尹建坤,田瑞丽,史建雨,靳瑞杰.超临界水氧化处理难降解废水的中试研究[J].绿色科技,2014,16(3):46-49. 被引量：4
4张霖琳,王超,刀谞,滕恩江,王业耀.京津冀地区城市环境空气颗粒物及其元素特征分析[J].中国环境科学,2014,34(12):2993-3000. 被引量：38
5陈季,张洪珍.浅谈人类与自然环境的相互关系[J].佳木斯师专学报,1991,9(3):48-52.
6吴耶.人驯化了狗，还是狗驯化了人[J].科技信息（山东）,2010(18):86-87.
7HAN ZhanGang,BOND Alan M,ZHAO Chuan.Recent trends in the use of polyoxometalate-based material for efficient water oxidation[J].Science China Chemistry,2011,54(12):1877-1887. 被引量：1
8杜润丽.超临界水氧化技术处理焦化废水[J].科技信息,2012(26):353-353.
9WEI Chao-hai HU Cheng-sheng WU Chao-fei YAN Bo.Supercritical gasification for the treatment of o-cresol wastewater[J].Journal of Environmental Sciences,2006,18(4):644-649. 被引量：4
10刘俊.超临界流体技术及其在环境保护中的应用[J].科技信息,2009(29). 被引量：1

Journal of Environmental Sciences

2007年第12期

浏览历史

内容加载中请稍等...