基于响应面法优化O,O-二甲基-O-3,5,6-三氯-2-吡啶基硫逐磷酸酯废水萃取工艺
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摘要
采用离心萃取机对O,O-二甲基-O-3,5,6-三氯-2-吡啶基硫逐磷酸酯合成过程含盐母液废水进行了萃取工艺研究,考察了萃取级数、氯仿与废水质量比、废水进料量对O,O-二甲基-O-3,5,6-三氯-2-吡啶基硫逐磷酸酯萃取效率的影响,利用Design-Expert软件的Box-Behnken模型对萃取工艺进行了优化,优化得到最佳萃取工艺为:氯仿与废水质量比为1.11∶1、废水进料流量为80 mL/min、萃取级数3级,萃取效率达到99.3%,萃取效率高于传统间歇萃取,成本低,适合工业化生产。
The extraction process of salt-containing mother liquor wastewater from o,o-dimethyl-o-(3,5,6-trichloro-2-pyridyl) phosphorothioate synthesis process was studied by using centrifugal extraction machine. Effect of extraction stage number, chloroform-wastewater mass ratio and the feed rate of wastewater on the extraction efficiency of o,o-dimethyl-o-(3,5,6-trichloro-2-pyridyl) phosphorothioate was investigated. Box-Behnken model of DesignExpert software was used to optimize the extraction process, and the best extraction process was obtained as follows: the mass ratio of extraction agent and waste water 1.11:1,the feed flow of waste water 80 mL/min, and the extraction stage number 3. Under above conditions, the extraction efficiency was up to 99.3%. The extraction efficiency is higher than that of traditional batch extraction process, and the cost is low, so the method is suitable for industrial production.
The extraction process of salt-containing mother liquor wastewater from o,o-dimethyl-o-(3,5,6-trichloro-2-pyridyl) phosphorothioate synthesis process was studied by using centrifugal extraction machine. Effect of extraction stage number, chloroform-wastewater mass ratio and the feed rate of wastewater on the extraction efficiency of o,o-dimethyl-o-(3,5,6-trichloro-2-pyridyl) phosphorothioate was investigated. Box-Behnken model of DesignExpert software was used to optimize the extraction process, and the best extraction process was obtained as follows: the mass ratio of extraction agent and waste water 1.11:1,the feed flow of waste water 80 mL/min, and the extraction stage number 3. Under above conditions, the extraction efficiency was up to 99.3%. The extraction efficiency is higher than that of traditional batch extraction process, and the cost is low, so the method is suitable for industrial production.
引文
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[2]宋小平,韩长日.农用化学品制造技术[M].北京:科学技术文献出版社, 2012:135-136.
[3]张伟.原药供应手册2011年版[M].北京:中国农业出版社, 2010:124-125.
[4]熊涤生.甲基毒死蜱是一种高效低毒的储粮防护剂[J].粮食加工,1991(2):18-20.
[5]杨伟.甲基毒死蜱的最新合成工艺[J].农药, 1990(3):51-52.
[6]王同涛.水溶剂法合成甲基毒死蜱[J].化工中间体, 2009,5(6):47-49.
[7]仵兆武.甲基毒死蜱的开发研究[J].广东化工, 2006, 33(3):18-20.
[8]胡跃华,胡辉,宋雪斌.水相法合成毒死蜱[J].农药, 2007,46(9):594-595.
[9]钱玉珍.毒死蜱绿色合成工艺研究[D].济南:山东大学, 2013.
[10]陆阳,陶京朝,张志荣.水溶剂法合成高效杀虫剂毒死蜱的研究[J].今日农药, 2008, 36(8):19-21.
[11]欧阳湘豫,林逢凯,王郁.微电池电解法处理甲基毒死蜱废水的研究[J].化学世界, 2000(s1):60+34.
[12]于文东,段五华,张成群,等.用离心萃取器连续逆流提取氢化可的松的研究[J].精细化工, 2001, 18(10):611-613.
[13]于文东,段五华,张成群,等.离心萃取器提取氢化可的松的工业试验研究[J].化工科技, 2001, 9(4):31-34.
[14]安路阳,刘睿,王钟欧,等.含酚废水离心萃取脱酚技术研究[J].环境工程, 2016(s1):62-65.
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