UASB处理系统中垃圾渗滤液结垢物的降解
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摘要
根据UASB系统的运行特点建立实验模拟系统,并对垃圾渗滤液进行水质监测与分析,掌握了渗滤液中钙离子含量的波动情况;以磷酸钠为沉淀剂,采用分布化学沉淀法处理垃圾渗滤液,使钙离子以含钙沉淀物形式进行沉淀;通过添加稀硫酸调节垃圾渗滤液的pH值后,含钙沉淀物再次形成;这些措施有效降解了垃圾渗滤液中的结垢物。结果表明,经烘干后每吨渗滤液产生的沉淀物质量达到6. 7 kg,钙去除率达到53. 6%,其实验条件为:向垃圾渗滤液添加的磷酸钠的物质的量比为n(Ca)∶n(P)=2. 5∶1,用体积比为25%的硫酸调节渗滤液清液的pH值至6,搅拌速率为300 r/min,静置时间为12 h;这些处理措施不仅减缓了装置的结垢速度以保护厌氧系统,还能够节约运行成本。
According to the operation characteristics of the UASB system,an experimental simulator was set up and the water quality of the landfill leachate was monitored and analyzed in order to master the fluctuation of calcium ion content in leachate. The landfill leachate was treated with sodium phosphate as precipitant by distributed chemical precipitation method so as to precipitate calcium ions in the form of calcium-containing precipitates. After adding dilute sulfuric acid to adjust the pH value of landfill leachate,calcium-containing precipitates were formed again. These measures effectively degraded the scale objects from landfill leachate. The results show that the precipitate weight per ton of leachate reaches 6. 7 kg after drying and the calcium removal rate reaches 53. 6% under the experimental conditions are as follows: the content ratio of sodium phosphate added to the leachate is n (Ca) ∶ n (P) = 2. 5∶ 1,pH value of landfill leachate is adjusted to 6 by using sulfuric acid with its volume ratio of 25%,stirring rate is 300 r/min and static time is 12 h. These treatment measures not only slow down the scaling speed of the device so as to protect the anaerobic system but also save the operating cost.
According to the operation characteristics of the UASB system,an experimental simulator was set up and the water quality of the landfill leachate was monitored and analyzed in order to master the fluctuation of calcium ion content in leachate. The landfill leachate was treated with sodium phosphate as precipitant by distributed chemical precipitation method so as to precipitate calcium ions in the form of calcium-containing precipitates. After adding dilute sulfuric acid to adjust the pH value of landfill leachate,calcium-containing precipitates were formed again. These measures effectively degraded the scale objects from landfill leachate. The results show that the precipitate weight per ton of leachate reaches 6. 7 kg after drying and the calcium removal rate reaches 53. 6% under the experimental conditions are as follows: the content ratio of sodium phosphate added to the leachate is n (Ca) ∶ n (P) = 2. 5∶ 1,pH value of landfill leachate is adjusted to 6 by using sulfuric acid with its volume ratio of 25%,stirring rate is 300 r/min and static time is 12 h. These treatment measures not only slow down the scaling speed of the device so as to protect the anaerobic system but also save the operating cost.
引文
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[3]BLUE C R,GIUFFRE A,MERGELSBERG S,et al.Chemical and physical controls on the transformation of amorphous calcium carbonate into crystalline CaCO3polymorphs[J].Geochimica Et Cosmochimica Acta,2017,196:179-196.
[4]TSUCHIYA Y,WADA Y,HIAKI T,et al.Effects of CO2fine bubble injection on reactive crystallization of dolomite from concentrated brine[J].Journal of Crystal Growth,2017,469:36-41.
[5]吴传余.垃圾渗滤液对水文资源的污染影响分析研究[J].环境科学与管理,2018,43(8):99-104.
[6]陈启汕,赵枚.浅谈城市垃圾填埋场水环境污染控制[J].资源节约与环保,2017(3):29-30.
[7]李堃宇.反渗透膜处理垃圾焚烧厂与填埋场渗滤液结垢机理研究[D].重庆:重庆大学,2016.
[8]王前,杨帆,徐期勇.焚烧炉渣填埋对填埋场土工膜结垢的影响[J].环境工程学报,2017,11(9):5262-5266.
[9]李玉荣.渗滤液输运管材HDPE的结垢腐蚀研究[D].成都:西南交通大学,2017.
[10]薛丹丹.垃圾渗滤液输送管道结垢堵塞的影响因素与防治研究[D].成都:西南交通大学,2008.
[11]何俊,赵宗泽,李跃华,等.物理方法除垢阻垢技术的研究现状及进展[J].工业水处理,2010,30(9):5-9.
[12]任旭.利用填埋气体去除渗滤液中成垢离子的化学机理研究[D].成都:西南交通大学,2013.
[13]郭希.基于填埋气体控制垃圾渗滤液输送系统阻塞的现场试验研究[D].成都:西南交通大学,2016.
[14]毛毓.基于多属性决策优化方法的渗滤液输运管道的材料选择研究[D].成都:西南交通大学,2016.
[15]杨承志,黄冲,冯自平,等.垃圾渗滤液浓缩用MVR蒸发管内CaCO3结垢过程数值分析[J].新能源进展,2016,4(4):320-327.
[16]李昌耀,胡敏捷,吴洪锋,等.石灰法处理磷化废水的试验研究[J].能源环境保护,2006,20(6):26-28.
[17]张勇,张丽彬.石灰法在处理金属表面磷化废水中的应用[J].工业安全与环保,2006,32(3):28-30.
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