| POLYMERS AND POLYMER MATRIX COMPOSITES |
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| Research Progress in Modification of Polyacrylate |
| MA Changpo1, LIU Xingchen2, LI Yongzan1, ZHANG Jian1, KANG Minxia1, QIU Zumin1
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1 School of Resources Environmental & Chemical Engineering, Nanchang University, Nanchang 330000, China
2 Chongyi Zhangyuan Tungsten Co., Ltd, Ganzhou 341300,China |
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Abstract Polyacrylate is a kind of macromolecule polymer synthesized from acrylate or methacrylate. It has good mechanical properties, weather resis-tance, acid and alkali resistance, its preparation process is simple and low in cost. It is widely used as a film-forming material for leather finishing, building coatings and wood. However, the application of pure polyacrylate is limited because of its poor antibacterial properties, mechanical properties and thermal stability. The functional behavior of polyacrylate can be improved by chemical modification and structural design.
The epoxy-acrylate obtained by using epoxy resin modified acrylate has the advantages of both, and has good weather resistance and thermal stability. At present, there are three methods of epoxy resin modifying acrylate: physical blending, esterification modification and graft copolymerization. Polyurethane is generally composed by isocyanate and active hydrogen compound, which can be divided into polyester polyurethane and polyether polyurethane. Polyurethane-acrylate composite emulsion curing film has excellent high temperature resistance, mechanical properties, and has been widely used in ink, coatings, adhesives and other fields. The methods of polyurethane modification include physical blending, composite copolymerization, core-shell copolymerization and interpenetrating polymer network. Fluoropolymer materials have many excellent properties, such as extremely low surface energy and excellent stability. The fluorine-containing groups are introduced into the acrylate emulsion. During the curing process, the fluorine-containing groups will accumulate on the surface of the membrane, protect the internal structure, and obtain the acrylate resin with excellent performance. Silicone is a kind of inorganic organic polymer, which can be used to connect inorganic matter with organic matter. There are mainly several different methods of silicone modified acrylate: polycondensation, free radical polymerization, hydrosilo-xane addition, interpenetrating network method, etc. The development of nanomaterials has also played a positive role in the modification of polyacrylate. Nanomaterials modified polyacrylates can not only make up for the deficiency of the emulsion itself, but also add the excellent cha-racteristics of nanoparticles. At present, the common nanoparticles mainly include ZnO, Fe3O4, Al2O3, TiO2 and so on.
This paper introduces the research progress of polyacrylate modified by epoxy resin, polyurethane, organic fluorine, silicone and nanoparticles. In this paper, the structural characteristics, modification methods and modification properties of these modified materials in recent years are reviewed, and their development direction is analyzed and prospected.
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Published: 31 August 2021
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| Fund:National Natural Science Foundation of China(51568048). |
About author:: Changpo Ma received his bachelor’s degree in chemical engineering and technology from Nanchang University in 2018, he is now studying for a master’s degree in chemical engineering at Nanchang University, majoring in the synthesis and application of polymer materials.
Zumin Qiu, male, was born in Ganzhou, Jiangxi Pro-vince in 1963. In 1984, he graduated from Jiangxi Institute of Technology with a bachelor’s degree in inorganic chemical engineering. In 1993, he obtained a master’s degree in chemical engineering in East China University of Science and Technology. In 1997, he obtained a doctor’s degree in industrial catalysis in South China University of Technology. He is director of Pharmaceutical Education Research Institute of National Association of Higher Medical Education, academic leader in the field of inorganic chemical engineering, and academic leader in Jiangxi Province. Zumin Qiu is mainly engaged in chemical industry and environmental protection research. Currently, he is hosting scientific research projects of the State Commission of Science and Technology (International Cooperation), the State Commission of Education, Natural Science Foundation of Jiangxi Province, Jiangxi Provincial Commission of Science and Technology, Jiangxi Provincial Commission of Education, Nanchang Municipal Commission of Science and Technology, etc. |
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