环保型无磷反渗透膜用阻垢剂的合成及性能研究
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摘要
选择以丙烯酸(AA)、2-丙烯酰胺-2-甲基丙磺酸(AMPS)、甲基丙烯酸羟乙酯(HEMA)为单体,以过硫酸铵为引发剂,叔丁醇为分子量调节剂,采用水溶液自由基聚合法对单体进行共聚反应,合成环保型三元共聚物阻垢剂。该共聚物是一种水溶性聚合物,其最佳合成条件为聚合温度80℃,聚合时间3 h,保温2.5 h。通过对共聚物结构表征和垢样的扫描电镜分析,表明分子中多种官能团协同作用,晶格畸变和络合增溶是其主要作用机理。静态和动态阻垢实验结果表明,共聚物具有较好的阻垢和分散氧化铁效果,性能明显优于4种传统阻垢剂,特别适用于高硬度高碱度的反渗透系统。
The environment-friendly terpolymer scale inhibitor was synthesized by aqueous solution free radical polymerization method. Three monomers are acrylic acid( AA),2-acrylamido-2-methylpropane sulfonic acid( AMPS) and hydroxyethyl methylacrylate( HEMA),the initiator used in this reaction is ammonium persulfate,and the tertiary butanol as molecular weight regulator. Terpolymer is a kind of water soluble polymer,which the optimum polymerization tempetature,holding time and reaction time are 80 ℃,2. 5 h and 3 h,respectively. The scanning electron microscope analysis of scale and structure of the copolymer show that the multiple functional groups cooperate with each other and lattice distortion and complexation solubilization are the main mechanisms. The results of static and dynamic experiments showed that the copolymer has better scale inhibition and dispersed iron oxide effects and the performance is superior to four kinds of traditional scale inhibitors. It is specially appropriate for the reverse osmosis system with high hardness and high alkalinity.
The environment-friendly terpolymer scale inhibitor was synthesized by aqueous solution free radical polymerization method. Three monomers are acrylic acid( AA),2-acrylamido-2-methylpropane sulfonic acid( AMPS) and hydroxyethyl methylacrylate( HEMA),the initiator used in this reaction is ammonium persulfate,and the tertiary butanol as molecular weight regulator. Terpolymer is a kind of water soluble polymer,which the optimum polymerization tempetature,holding time and reaction time are 80 ℃,2. 5 h and 3 h,respectively. The scanning electron microscope analysis of scale and structure of the copolymer show that the multiple functional groups cooperate with each other and lattice distortion and complexation solubilization are the main mechanisms. The results of static and dynamic experiments showed that the copolymer has better scale inhibition and dispersed iron oxide effects and the performance is superior to four kinds of traditional scale inhibitors. It is specially appropriate for the reverse osmosis system with high hardness and high alkalinity.
引文
[1]齐维维.低磷反渗透阻垢剂性能研究及其机理初探[D].沈阳:东北大学,2009:1-4.
[2]李琴,于萍,罗运柏,等.反渗透膜国产阻垢剂的阻垢性能试验[J].工业水处理,2006,26(7):30-33.
[3]严备齐,王志斌,靳紫阳,等.反渗透阻垢剂阻垢性能评价[J].工业水处理,2010,30(1):90-93.
[4]姜红静,刘振法,王丽梅,等.反渗透阻垢剂的动态阻垢性能研究及垢样分析[J].水处理技术,2008,34(9):50-53.
[5]胡晓静,刘振法,武秀丽,等.环境友好型缓蚀阻垢剂的研制及性能研究[J].水处理技术,2010,36(3):38-41.
[6]Gao Yuhua,Liu Zhenfa,Zhang Lihui,et al.Synthesis,characterization and scale inhibition of biodegradable polyaspartic acid derivative[C]//2009 3rd International Conference on Bioinformatics and Biomedical Engineering.USA:IEEE,2009:11-16.
[7]杜启云,周伟生.反渗透膜用阻垢剂的研制与应用研究[J].膜科学与技术,2008,28(6):76-78.
[8]余嵘,逯佩宁,严程,等.环境友好型AA/MA/HEMA共聚物阻垢剂的合成及阻垢性能研究[J].功能材料与器件学报,2015,21(4):42-53.
[9]梁淳淳.马来酸酐、丙烯酸、乙酸乙酸酯三元共聚物的合成及其性能研究[D].上海:华东理工大学,2013:19-41.
[10]郦和生,谢文州.反渗透膜阻垢剂评价方法的研究进展[J].工业水处理,2010,30(3):1-4.
[11]Greeberg G,Hasson D,Semiat R.Limits of recovery imposed by calcium phosphate precipitation[J].Desalination,2005,183(1/2/3):273-288.
[12]朱诚身.聚合物结构分析[M].北京:科学出版社,2004.
[13]朱志良,李继文,倪亚明.聚羧酸类阻垢剂对碳酸钙的沉淀及溶解过程的影响研究[J].工业水处理,2001,21(6):7-10.
[14]田彩莉,姜红静,杨维之,等.适用于高硬度水质的反渗透阻垢剂的研究[J].工业水处理,2007,27(11):38-41.
[15]魏晓飞.新型多羧基磺酸共聚物阻垢剂的合成与性能研究[D].济南:山东大学,2012:5-7.
[16]Sutio J W,Marner W J,Ritter R B.The history and status of research in fouling of heat exchangers in cooling water service[J].Can J Chem Eng,1977,55:374.
[17]李裕芳.阻垢剂分散剂控制沉积机理探讨[J].工业水处理,1986,8(4):6-10.
[2]李琴,于萍,罗运柏,等.反渗透膜国产阻垢剂的阻垢性能试验[J].工业水处理,2006,26(7):30-33.
[3]严备齐,王志斌,靳紫阳,等.反渗透阻垢剂阻垢性能评价[J].工业水处理,2010,30(1):90-93.
[4]姜红静,刘振法,王丽梅,等.反渗透阻垢剂的动态阻垢性能研究及垢样分析[J].水处理技术,2008,34(9):50-53.
[5]胡晓静,刘振法,武秀丽,等.环境友好型缓蚀阻垢剂的研制及性能研究[J].水处理技术,2010,36(3):38-41.
[6]Gao Yuhua,Liu Zhenfa,Zhang Lihui,et al.Synthesis,characterization and scale inhibition of biodegradable polyaspartic acid derivative[C]//2009 3rd International Conference on Bioinformatics and Biomedical Engineering.USA:IEEE,2009:11-16.
[7]杜启云,周伟生.反渗透膜用阻垢剂的研制与应用研究[J].膜科学与技术,2008,28(6):76-78.
[8]余嵘,逯佩宁,严程,等.环境友好型AA/MA/HEMA共聚物阻垢剂的合成及阻垢性能研究[J].功能材料与器件学报,2015,21(4):42-53.
[9]梁淳淳.马来酸酐、丙烯酸、乙酸乙酸酯三元共聚物的合成及其性能研究[D].上海:华东理工大学,2013:19-41.
[10]郦和生,谢文州.反渗透膜阻垢剂评价方法的研究进展[J].工业水处理,2010,30(3):1-4.
[11]Greeberg G,Hasson D,Semiat R.Limits of recovery imposed by calcium phosphate precipitation[J].Desalination,2005,183(1/2/3):273-288.
[12]朱诚身.聚合物结构分析[M].北京:科学出版社,2004.
[13]朱志良,李继文,倪亚明.聚羧酸类阻垢剂对碳酸钙的沉淀及溶解过程的影响研究[J].工业水处理,2001,21(6):7-10.
[14]田彩莉,姜红静,杨维之,等.适用于高硬度水质的反渗透阻垢剂的研究[J].工业水处理,2007,27(11):38-41.
[15]魏晓飞.新型多羧基磺酸共聚物阻垢剂的合成与性能研究[D].济南:山东大学,2012:5-7.
[16]Sutio J W,Marner W J,Ritter R B.The history and status of research in fouling of heat exchangers in cooling water service[J].Can J Chem Eng,1977,55:374.
[17]李裕芳.阻垢剂分散剂控制沉积机理探讨[J].工业水处理,1986,8(4):6-10.
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