城市污泥慢速热解过程中氮的转化规律

doi:10.16085/j.issn.1000-6613.2016.01.041

化工进展 ›› 2016, Vol. 35 ›› Issue (01): 302-307.DOI: 10.16085/j.issn.1000-6613.2016.01.041

城市污泥慢速热解过程中氮的转化规律

郭明山^1,2, 金晶^1,2, 林郁郁^1,2, 王永贞^1,2, 侯封校^1,2

1 上海理工大学能源与动力工程学院, 上海 200093;
2 上海理工大学协同创新研究院, 上海 200093

收稿日期:2015-07-09 修回日期:2015-08-14 出版日期:2016-01-05 发布日期:2016-01-05
通讯作者: 金晶,教授,博士生导师。E-mail:alicejin001@163.com。
作者简介:郭明山(1990-),男,硕士研究生。E-mail:gmsazxq999@163.com。
基金资助:
上海市基础研究重点项目(14JC1404800)及国家科技支撑计划项目(2015BAA04B03)。

Transformation mechanism of nitrogen of municipal sewage sludge in the slow pyrolysis process

GUO Mingshan^1,2, JIN Jing^1,2, LIN Yuyu^1,2, WANG Yongzhen^1,2, HOU Fengxiao^1,2

1 School of Energy and Power Engineering, University of Shanghai for Science and Technology, Shanghai 200093, China;
2 Collaborative Innovation Research Institute, University of Shanghai for Science and Technology, Shanghai 200093, China

Received:2015-07-09 Revised:2015-08-14 Online:2016-01-05 Published:2016-01-05

摘要/Abstract

摘要： 利用热重-质谱联用(TG-MS)技术研究城市污泥慢速热解特性及含氮气体产物的生成规律,同时利用原位红外光谱仪实时检测固体表面官能团的变化。研究结果表明:初沉污泥在500℃之前热解已基本完成,二沉污泥由于添加了矿物质盐类,在700℃左右仍有一个较大的失重峰;二沉污泥热解过程HCN和NH₃总生成量均小于初沉污泥,即二沉污泥所加矿物质抑制了HCN和NH₃释放;但温度大于400℃时所加矿物质对HNCO生成具有一定促进作用;污泥中蛋白质热分解会产生环酰胺类物质、含氮杂环化合物和腈类物质,并最终转化为HCN,这是污泥热解过程中HCN的主要来源;400℃以下NH₃主要来自铵盐分解和HCN转化,蛋白质热分解对于NH₃生成贡献很小;400℃以上基本检测不到NH₃生成,即较高温度下挥发分二次反应对NH₃生成几乎没有影响;300~480℃,污泥中木质素裂解产生了大量含氧自由基,促使HCN转化为N₂O,HNCO则最终转化成了NO。

关键词: 城市污泥, 慢速热解, 氰化氢, 氨

Abstract: The TG-MS technique was used to analyze the slow pyrolysis characteristics of municipal sewage sludge and the transformation mechanism of gaseous nitrogen compounds in the pyrolysis process. The dynamic change of functional groups on the surface of solid residual coke in sludge pyrolysis process was detected by an in-situ infrared spectrometer. Results showed that the pyrolysis process of primary sludge has been finished before 500℃ whereas due to the addition of mineral salts there is a relatively large weightlessness peak around 700℃ in the secondary sludge pyrolysis process. The generations of both HCN and NH₃ in secondary sludge pyrolysis process are less than those of primary sludge. It means that release of HCN and NH₃ is restrained on account of the addition of mineral substances. Whereas the added gives rise to the promoting of HNCO above 400℃. Cyclic amide materials, nitrogenous heterocyclic compounds and nitrile materials can be produced from the thermal decomposition of protein and those compounds are eventually converted to HCN, which is the main source of HCN in the pyrolysis process. When the temperature is below 400℃, NH₃ is mainly derived from the decomposition of ammonium salt and the conversion from HCN, while the thermal decomposition of protein contributes slightly to the generation of NH₃. When the temperature is above 400℃, NH₃ has not been detected. It means that the secondary reactions of volatile have minor impact on the formation of NH₃ in this temperature range. In the range of 300-480℃, a large number of oxygen free radicals is produced from thermal decomposition of lignin, this leads to the conversion of HCN into N₂O and the conversion of HNCO into NO.

Key words: municipal sewage sludge, slow pyrolysis, hydrogen cyanide, ammonia

中图分类号:

郭明山, 金晶, 林郁郁, 王永贞, 侯封校. 城市污泥慢速热解过程中氮的转化规律[J]. 化工进展, 2016, 35(01): 302-307.

GUO Mingshan, JIN Jing, LIN Yuyu, WANG Yongzhen, HOU Fengxiao. Transformation mechanism of nitrogen of municipal sewage sludge in the slow pyrolysis process[J]. Chemical Industry and Engineering Progree, 2016, 35(01): 302-307.

参考文献

[1] KIM Y,PARKER W. A technical and economic evaluation of the pyrolysis of sewage sludge for the production of bio-oil[J]. Bioresource Technology,2008,99(5):1409-1416.
[2] 陈涛,孙水裕,刘敬勇,等. 城市污水污泥焚烧二次污染物控制研究进展[J]. 化工进展,2010,29(1):157-162.
[3] 张辉,胡勤海,吴祖成,等. 城市污泥能源化利用研究进展[J]. 化工进展,2013,32(5):1145-1151.
[4] ZHANG Jun,TIAN Yu,CUI Yanni,et al. Key intermediates in nitrogen transformation during microwave pyrolysis of sewage sludge:a protein model compound study[J]. Bioresour. Technol., 2013,132:57-63.
[5] 张娜. 污泥热解过程中氮的迁移特性研究[D]. 沈阳:沈阳航空航天大学,2013.
[6] CHEN Hongfang,NAMIOKA Tomoaki1,YOSHIKAWA Kunio. Characteristics of tar, NO_x precursors and their absorption performance with different scrubbing solvents during the pyrolysis of sewage sludge[J]. Applied Energy,2011,88(12):5032-5041.
[7] TIAN Fujun,LI Baoqing,CHEN Yong,et al. Formation of NO_x precursors during the pyrolysis of coal and biomass. Part Ⅴ:pyrolysis of a sewage sludge[J]. Fuel,2002,81:2203-2208.
[8] XIE Z,FENG J,ZHAO W,et al. Formation of NO_x and SO_x precursors during the pyrolysis of coal and biomass. Part Ⅳ. Pyrolysis of a set of Australian and Chinese coals[J]. Fuel,2001,80(15):2131-2138.
[9] OLIVIER Debono,AUDREY Villot. Nitrogen products and reaction pathway of nitrogen compounds during the pyrolysis of various organic wastes[J].Journal of Analytical and Applied Pyrolysis,2015, 114:222-234.
[10] 谭涛. 污水污泥含氮模型化合物的构建及热解过程中氮转化途径研究[D]. 哈尔滨:哈尔滨工业大学,2011.
[11] HANSSON K M,SAMUELSSON J,TULLIN C,et al. Formation of HNCO,HCN, and NH₃ from the pyrolysis of bark and nitrogen-containing model compounds[J]. Combustion and Flame, 2004,137(3):265-277.
[12] RAUNIER S,CHIAVASSA T,MARINELLI F,et al. Reactivity of HNCO with NH₃ at low temperature monitored by FTIR spectroscopy:formation of NH₄⁺OCN-[J]. Chemical Physics Letters, 2003,368(5/6):594-600.
[13] RATCLIFF J M A,MEDLEY E E,SIMMONDS P G. Pyrolysis of amino acids. Mechanistic considerations[J]. The Journal of Organic Chemistry,1974,39(11):1481-1490.
[14] HANSSON K M,SAMUELSSON J,AMAND L E,et al. The temperature's influence on the selectivity between HNCO and HCN from pyrolysis of 2,5-diketopiperazine and 2-pyridone[J]. Fuel, 2003,82(18):2163-2172.
[15] CONESA J A,MARCILLA A,PRATS D,et al. Kinetic study of the pyrolysis of sewage sludge[J]. Waste Management & Research, 1997,15(3):293-305.
[16] 翁焕新,金骏,刘瓒,等. 污泥干化过程中氨的释放与控制[J]. 中国环境科学,2011,31(7):1171-1177.
[17] HÄMÄLÄINEN Jouni P,AHO Martti J. Effect of fuel composition on the conversion of volatile solid fueI-N to N₂O and NO[J]. Fuel, 1994,74(12):1922-1924.

城市污泥慢速热解过程中氮的转化规律

Transformation mechanism of nitrogen of municipal sewage sludge in the slow pyrolysis process

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