D301树脂吸附废水中草甘膦的研究
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摘要
通过静态实验探究了吸附剂用量、氯离子浓度、磷酸盐浓度对D301树脂吸附废水中草甘膦的效果影响,同时研究了该吸附过程的动力学、等温线。结果表明,废水中草甘膦氯离子和磷酸盐浓度越高,D301树脂吸附效果越差,草甘膦去除率越低。该吸附过程符合Langmuir方程,为单层吸附,最大吸附量约为181.8 mg/g,符合二级动力学模型。动态实验结果表明,当D301树脂吸附草甘膦达到穿透体积时,草甘膦去除率为79.3%。
Through static ex periments, the effects of adsorbent dosage, chloride ion concentration and phosphate concentration on glyphosate wastewater treatment effect were investigated, and the kinetics and isotherms of the adsorption process were studied. The results showed that the higher the concentration of chloride and phosphate, the lower the removal rate of glyphosate, and the worse the adsorption effect. The adsorption process conformed to Langmuir equation,which was single-layer adsorption, the maximum adsorption amount was about 181.8 mg/g, and conformed to the second-order kinetic model. The dynamic experiments results showed that the removal rate of glyphosate was 79.3% when the penetration volume of glyphosate was reached by D301 resin.
Through static ex periments, the effects of adsorbent dosage, chloride ion concentration and phosphate concentration on glyphosate wastewater treatment effect were investigated, and the kinetics and isotherms of the adsorption process were studied. The results showed that the higher the concentration of chloride and phosphate, the lower the removal rate of glyphosate, and the worse the adsorption effect. The adsorption process conformed to Langmuir equation,which was single-layer adsorption, the maximum adsorption amount was about 181.8 mg/g, and conformed to the second-order kinetic model. The dynamic experiments results showed that the removal rate of glyphosate was 79.3% when the penetration volume of glyphosate was reached by D301 resin.
引文
[1]王军华,王易芬,陈蕾蕾,等.除草剂草甘膦微生物降解技术研究进展[J].江苏农业科学, 2016, 44(4):8-12.
[2]张一宾.世界农药大市场呈现十大特点[J].农资与市场, 2016(7):39-46.
[3]施娟娟,马亚芳,倪龙博,等. 3个草甘膦复配组合对非耕地杂草的防除效果[J].杂草科学, 2015(1):48-52.
[4]宋宝安,吴剑.我国农药产业创新发展的路径思考[J].农药市场信息, 2015(20):8-12; 22.
[5]汪建沃.环保助推农药行业转型升级[J].今日农药, 2015(8):14-15.
[6]张全兴,张政朴,李爱民,等.我国离子交换与吸附树脂的发展历程回顾与展望[J].高分子学报, 2018(7):814-828.
[7] Dabrowski A. Adsorption-from Theory to Practice[J]. Advances in Colloid&Interface Science, 2001, 93(1):135-224.
[8]编委会国家环境保护总局水和废水监测分析方法.水和废水监测分析方法[M]. 4版.北京:中国环境科学出版社, 2002.
[9]吴哲峰,邱晖,程棋波,等.膜分离-氧化法去除草甘膦生产线上副产盐中的有机物[J].农药, 2015(10):715-719.
[10]吴哲峰.草甘膦生产线上副产固体盐精制研究[D].杭州:浙江理工大学, 2016.
[11]陈玉强,张胜寒.高分子除氯剂对水中氯离子的吸附机理[J].化工环保, 2018, 38(2):185-190.
[12]沈丽静,乐清华,杨毓智,等.活性炭处理草甘膦废水的静态吸附研究[J].化学工程师, 2006, 20(10):46-49.
[13] Gimsing A L, Borggaard O K. Phosphate and Glyphosate Adsorption by Hematite and Ferrihydrite and Comparison with Other Variable-Charge Minerals[J]. Clays&Clay Minerals, 2007, 55(1):108-114.
[14] Gimsing A L, Borggaard O K, Bang M. Influence of Soil Composition on Adsorption of Glyphosate and Phosphate by Contrasting Danish Surface Soils[J]. European Journal of Soil Science, 2004,55(1):183-191.
[15] Khenifi A, Derriche Z, Mousty C, et al. Adsorption of Glyphosate and Glufosinate by Ni2AlNO3Layered Double Hydroxide[J]. Applied Clay Science, 2010, 47(3):362-371.
[16]赵平,张月萍,任鹏. AB-8大孔树脂对葡萄籽原花青素的吸附过程[J].化工学报, 2013, 64(3):980-985.
[17]袁志文,宋艳艳.锰盐沉淀法处理草甘膦废水的草甘膦回收试验[J].净水技术, 2012, 31(1):55-58.
[2]张一宾.世界农药大市场呈现十大特点[J].农资与市场, 2016(7):39-46.
[3]施娟娟,马亚芳,倪龙博,等. 3个草甘膦复配组合对非耕地杂草的防除效果[J].杂草科学, 2015(1):48-52.
[4]宋宝安,吴剑.我国农药产业创新发展的路径思考[J].农药市场信息, 2015(20):8-12; 22.
[5]汪建沃.环保助推农药行业转型升级[J].今日农药, 2015(8):14-15.
[6]张全兴,张政朴,李爱民,等.我国离子交换与吸附树脂的发展历程回顾与展望[J].高分子学报, 2018(7):814-828.
[7] Dabrowski A. Adsorption-from Theory to Practice[J]. Advances in Colloid&Interface Science, 2001, 93(1):135-224.
[8]编委会国家环境保护总局水和废水监测分析方法.水和废水监测分析方法[M]. 4版.北京:中国环境科学出版社, 2002.
[9]吴哲峰,邱晖,程棋波,等.膜分离-氧化法去除草甘膦生产线上副产盐中的有机物[J].农药, 2015(10):715-719.
[10]吴哲峰.草甘膦生产线上副产固体盐精制研究[D].杭州:浙江理工大学, 2016.
[11]陈玉强,张胜寒.高分子除氯剂对水中氯离子的吸附机理[J].化工环保, 2018, 38(2):185-190.
[12]沈丽静,乐清华,杨毓智,等.活性炭处理草甘膦废水的静态吸附研究[J].化学工程师, 2006, 20(10):46-49.
[13] Gimsing A L, Borggaard O K. Phosphate and Glyphosate Adsorption by Hematite and Ferrihydrite and Comparison with Other Variable-Charge Minerals[J]. Clays&Clay Minerals, 2007, 55(1):108-114.
[14] Gimsing A L, Borggaard O K, Bang M. Influence of Soil Composition on Adsorption of Glyphosate and Phosphate by Contrasting Danish Surface Soils[J]. European Journal of Soil Science, 2004,55(1):183-191.
[15] Khenifi A, Derriche Z, Mousty C, et al. Adsorption of Glyphosate and Glufosinate by Ni2AlNO3Layered Double Hydroxide[J]. Applied Clay Science, 2010, 47(3):362-371.
[16]赵平,张月萍,任鹏. AB-8大孔树脂对葡萄籽原花青素的吸附过程[J].化工学报, 2013, 64(3):980-985.
[17]袁志文,宋艳艳.锰盐沉淀法处理草甘膦废水的草甘膦回收试验[J].净水技术, 2012, 31(1):55-58.
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