重金属废水处理剂的研制及应用研究
摘要
工业废水中所含的重金属进入环境后很难被生物降解,因其参与食物链并最终在生物体内积累,破坏生物体正常生理代谢活动,给生物环境带来极大的污染。所以,对重金属废水的治理一直是人们关注的焦点。
在前人研究的基础上,本研究选用改性的天然磷灰石为原料,添加粘结剂和发泡剂,采用滚动制粒成型的方法,制备性能优良的颗粒状重金属废水处理剂,用静态法和动态法进行去除废水中的重金属离子试验,并对失效的水处理剂进行了处理,避免二次污染。
废水处理剂制备试验结果表明,Al和N-1分别作为粘结剂和发泡剂的效果好,最佳的制备条件是:-100目占75%的改性磷灰石配加6%clay1和0.2%N-1、水分10%、造球时间为12min,烘干后在700℃下焙烧20min,在该条件下得到的水处理剂去除pb~(2+)能力达661.10mg/g,有很好的脱色作用和降低COD的功能。
较低的pH值,较长的处理时间,较高的废水浓度和较高的反应温度可适当提高水处理剂去除pb~(2+)能力,粒度在1-5mm之间,比较符合生产的要求,去除重金属离子能力与去除剂的比表面积决定。失效的水处理剂TCLP试验测得Pb~(2+)溶出浓度为8.4mg/L,溶出率为0.10%,超出了国家排放标准,在900℃下焙烧3h后,pb~(2+)溶出浓度仅为1.8mg/L,达到国家排放标准。以10%比例掺入粘土制砖后,砖的抗压强度仍能达到国家标准,pb~(2+)溶出浓度只有0.03mg/g,不会造成二次污染。
综合效益分析表明,水处理剂是一种质优价廉的最具有应用潜力和开发价值的环境矿物材料。
Industrial wastewater containing heavy metal ions contaminates biotic environment greatly. Because heavy metal ions have a low-grade biodegradability, play along with food chain and be accumulated in living body at last, destruct living body's normal metabolism. Now the treatment of wastewater containing heavy metal ions has been paid great attention.
In this article, basing on the existing study, the granular wastewater treatment agent which has blue-chip property for heavy metal ions contained wastewater prepared with modified natural apatites are rolled with the addition of water, in discs. During the formation, adhesive and foaming agent are use for improving the property of agent. The static and dynamic methods were used in the experiment of attenuating the heavy metal ions containing wastewater, and the invalid agent was treated to avoid secondary pollution.
The results of preparation experiments of the wastewater treatment agent for heavy metal containing wastewater indicate that adding Al as adhesive and N-l as foaming agent are benefit for the property of the wastewater treatment agent. The optimum conditions to prepare wastewater treatment agent are: the fraction of -100 mesh of the modified natural apatites' particle size is 75%, clayl is 6%, N-l is 0.2%, moisture content is 10%, roasting temperature is 700 C and the retaining time is 20 minutes. Under the optimum condition, the removal ability of Pb2+ of the wastewater treatment agent can reach 661.10mg/g, have the decoloration and decline COD.
Excellent attenuation of Pb 2+ is obtained at low pH, long conditioning time, high temperature and high initial concentration of heavy metal ions. To adapt the request of produce, the agent's size are required l-5mm. The specific surface area of hydroxyapatite mainly controls the removal ability of Pb2+ of the wastewater treatment agent. A TCLP test was conducted on the invalid agent. The centrifuged supernatant was found to contain 8.4mg/L Pb2+ which excess the national discharge standard, the exchanging ratio is 0.10%. After 3 hours of firing at 900 C, the concentration of Pb2+ is only 1.8mg/L, reach the national discharge standard. The compressive strength of brick manufacture with 10% of the invalid agent in brick clay get up to the national standard, the released concentration of Pb2+ is no other than 0.03mg/L, no secondary pollution.
With the analysis of overall benefits, the wastewater treatment agent for heavy metal containing wastewater is a most potential environmental mineral material, which property is good and cost is cheap.
在前人研究的基础上,本研究选用改性的天然磷灰石为原料,添加粘结剂和发泡剂,采用滚动制粒成型的方法,制备性能优良的颗粒状重金属废水处理剂,用静态法和动态法进行去除废水中的重金属离子试验,并对失效的水处理剂进行了处理,避免二次污染。
废水处理剂制备试验结果表明,Al和N-1分别作为粘结剂和发泡剂的效果好,最佳的制备条件是:-100目占75%的改性磷灰石配加6%clay1和0.2%N-1、水分10%、造球时间为12min,烘干后在700℃下焙烧20min,在该条件下得到的水处理剂去除pb~(2+)能力达661.10mg/g,有很好的脱色作用和降低COD的功能。
较低的pH值,较长的处理时间,较高的废水浓度和较高的反应温度可适当提高水处理剂去除pb~(2+)能力,粒度在1-5mm之间,比较符合生产的要求,去除重金属离子能力与去除剂的比表面积决定。失效的水处理剂TCLP试验测得Pb~(2+)溶出浓度为8.4mg/L,溶出率为0.10%,超出了国家排放标准,在900℃下焙烧3h后,pb~(2+)溶出浓度仅为1.8mg/L,达到国家排放标准。以10%比例掺入粘土制砖后,砖的抗压强度仍能达到国家标准,pb~(2+)溶出浓度只有0.03mg/g,不会造成二次污染。
综合效益分析表明,水处理剂是一种质优价廉的最具有应用潜力和开发价值的环境矿物材料。
Industrial wastewater containing heavy metal ions contaminates biotic environment greatly. Because heavy metal ions have a low-grade biodegradability, play along with food chain and be accumulated in living body at last, destruct living body's normal metabolism. Now the treatment of wastewater containing heavy metal ions has been paid great attention.
In this article, basing on the existing study, the granular wastewater treatment agent which has blue-chip property for heavy metal ions contained wastewater prepared with modified natural apatites are rolled with the addition of water, in discs. During the formation, adhesive and foaming agent are use for improving the property of agent. The static and dynamic methods were used in the experiment of attenuating the heavy metal ions containing wastewater, and the invalid agent was treated to avoid secondary pollution.
The results of preparation experiments of the wastewater treatment agent for heavy metal containing wastewater indicate that adding Al as adhesive and N-l as foaming agent are benefit for the property of the wastewater treatment agent. The optimum conditions to prepare wastewater treatment agent are: the fraction of -100 mesh of the modified natural apatites' particle size is 75%, clayl is 6%, N-l is 0.2%, moisture content is 10%, roasting temperature is 700 C and the retaining time is 20 minutes. Under the optimum condition, the removal ability of Pb2+ of the wastewater treatment agent can reach 661.10mg/g, have the decoloration and decline COD.
Excellent attenuation of Pb 2+ is obtained at low pH, long conditioning time, high temperature and high initial concentration of heavy metal ions. To adapt the request of produce, the agent's size are required l-5mm. The specific surface area of hydroxyapatite mainly controls the removal ability of Pb2+ of the wastewater treatment agent. A TCLP test was conducted on the invalid agent. The centrifuged supernatant was found to contain 8.4mg/L Pb2+ which excess the national discharge standard, the exchanging ratio is 0.10%. After 3 hours of firing at 900 C, the concentration of Pb2+ is only 1.8mg/L, reach the national discharge standard. The compressive strength of brick manufacture with 10% of the invalid agent in brick clay get up to the national standard, the released concentration of Pb2+ is no other than 0.03mg/L, no secondary pollution.
With the analysis of overall benefits, the wastewater treatment agent for heavy metal containing wastewater is a most potential environmental mineral material, which property is good and cost is cheap.
引文
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[24] 胥焕岩.磷灰石吸附水溶液中镉离子的研究[D].武汉:武汉化工学院材料科学与工程系,2001.
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[28] 刘和平,郑洁明,刘巧丽.铅和镉在粘土层中渗透、迁移、转化的研究[J].环境科学研究,1997,10(4):56-60.
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[31] 胥焕岩,刘羽,石和彬.磷灰石及其对水溶液中Cd~(2+)离子的固定作用[J],矿产保护与利用,2000,4:21-26.
[32] 罗惠华,钟康年,刘羽.羟基磷灰石吸附剂去除铬黄工业废水中铅离子的研究[J],岩石矿物学杂志,2001,20(4):587-589.
[33] 刘羽,钟康年,胡文云 用水热法羟基磷灰石去除溶液中铅离子的研究[J],武汉化工学院学报,1998,20(1):39-42.
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[35] 罗惠华,石和彬,钟康年等 天然及改性碳氟磷灰石对水中pb~(2+)的吸附性能研究[J],非金属矿,2000,23(6):43-49.
[36] 石和彬,刘羽,罗惠华等磷矿石的吸附性能研究[J],武汉化工学院学报,1999,21(3):34-37.
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[2] 杨淑英,张增强.我国水资源面临的问题与对策[J].环境保护,1997,(11):6-8,15.
[3] 孙胜龙编著.环境材料[M].北京:化学工业出版社,2002:185。
[4] 惠秀娟编,环境毒理学[M].北京:化学工业出版社,2003:80。
[5] 陈坚,堵国成编著.环境友好材料的生产与应用[M].北京:化学工业出版社,2002:287.
[6] 孟祥和,胡国飞编著.重金属废水处理[M].北京:化学工业出版社,2000:12-16.
[7] 黄继国,张永祥,吕斯濠.重金属废水处理技术综述[J].世界地质,1999,18(4):83-86.
[8] 张建梅,韩志萍,王亚军.重金属废水的治理和回收综述[J].湖州师范学院学报,2002,24(3):48-52.
[9] 杨越冬,周永国,齐印阁等.脱乙酰甲壳质处理含铅废水[J],1995(8):9-11.
[10] 陈泉水.粉煤灰处理含重金属废水试验研究[J],化工矿物与加工,2001,6:11-13.
[11] 王学杰.廉价吸附材料在污水处理中的应用[J],工业水处理,1992,12(3):11-13.
[12] Suzuki T, Hatsushika T, Hayakaw A Y. Synthetic hydroxyapatite employed as inorganic cation exchangers [J]. Jurnal of the Chemical Society Faraday Transaction I, 1981, 77: 1059-1062.
[13] 胡文云.磷灰石吸附水溶液中铅离子的研究[D],武汉:武汉化工学院材料工程系,1996.
[14] 刘羽,胡文云,钟康年.活化天然磷灰石用于去除水溶液中铅离子[J].矿物岩石地地球化学通报,1997,16(sup.1):39-40.
[15] 石和彬,刘羽,罗惠华等.磷灰石固定水溶液中铅离子研究[J],地质科技情报,1999,18(2):73-76.
[16] 山本良一编著.环境材料[M].王天民译.北京:化学工业出版社,1997.
[17] 陶维屏,苏德辰.中国非金属矿产资源及其利用与开发.北京:地震出版社,2002:46.
[18] 阿部光雄.当代离子交换技术[M],王方等编译,北京:化学工业出版社,1993:301-306.
[19] Suzuki T, Hatsushika T, Hayakaw a Y. synthetic hydroxyapatites employed as inorganic cation exchangers[J]. Journal of the Chemical Society Faraday Transaction I, 1981, 77: 1059-1062.
[20] 铃木乔.环境科学会志,1991,29(11):918-924.
[21] Suzuki T, Ishigaki K, Miyske M. Synthetic hydroxyapatites as inorganic cation exchangers: (3)exchange chacteritics of lead ion(Pb~(2+))[J]. Journal of the Chemical Society Faraday Transaction I, 1984, 80:3157-3165.
[22] Miyske M, Ishigaki K, Suzuki T. Structure refinements of Pb~(2+) ion—exchanged apatites by X-ray powder pattern-fitting. Journal of Solid Chemistry, 1986, 61: 230-235.
[23] Livinstone A. An appetite high in lead from wanlockhead[J] Stratchlyde pregion Mineralogical Magazine. 1994 58:159-163.
[24] 胥焕岩.磷灰石吸附水溶液中镉离子的研究[D].武汉:武汉化工学院材料科学与工程系,2001.
[25] Ma Qiying, Traina S J, Logan T J et al. In situ lead immobilization by apatite[J]. Environmental Science and Technology, 1993,27:1803-1810.
[26] 俞苏蒙,王振刚.铅污染地区儿童血浆氨基酸水平的研究[J].环境保护,1995,(2):44-47.
[27] 李华斌,戚其平.铅对健康的影响研究进展[J],环境导报,1999,(1):32-35.
[28] 刘和平,郑洁明,刘巧丽.铅和镉在粘土层中渗透、迁移、转化的研究[J].环境科学研究,1997,10(4):56-60.
[29] 廖自基.环境中微量重金属元素的污染危害与迁移转化[M].北京:科学出版社,1989:85.
[30] 彭儒,罗廉明.磷矿选矿.武汉:武汉测绘科技大学出版社,1992,14-16.
[31] 胥焕岩,刘羽,石和彬.磷灰石及其对水溶液中Cd~(2+)离子的固定作用[J],矿产保护与利用,2000,4:21-26.
[32] 罗惠华,钟康年,刘羽.羟基磷灰石吸附剂去除铬黄工业废水中铅离子的研究[J],岩石矿物学杂志,2001,20(4):587-589.
[33] 刘羽,钟康年,胡文云 用水热法羟基磷灰石去除溶液中铅离子的研究[J],武汉化工学院学报,1998,20(1):39-42.
[34] 刘羽,钟康年,胡文云.海口磷灰石的矿物学及pb~(2+)吸附特性研究[J],武汉化工学院学报,1996,18(4):31-35.
[35] 罗惠华,石和彬,钟康年等 天然及改性碳氟磷灰石对水中pb~(2+)的吸附性能研究[J],非金属矿,2000,23(6):43-49.
[36] 石和彬,刘羽,罗惠华等磷矿石的吸附性能研究[J],武汉化工学院学报,1999,21(3):34-37.
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