1、Fabrication of UV
Novel UV-curable methacrylate functionalized fluorosilicone resin (MAFSR) and sulfhydryl functionalized fluorosilicone resin (SFSR) were synthesized respectively. The molecular structure, UV curing process, thermal properties and surface properties were studied.
2、氟硅改性无溶剂环氧涂料的制备与性能
Fluorinated amino silicone oil (FAS) was prepared by modifying amino silicone oil (AS) with tridecafluorooctyl methacrylate (TFM), and epoxy resin (EP) was modified with FAS.
3、氟硅树脂改性紫外光固化易清洁涂层的制备及性能研究_百度文库
Herein, the work aims to propose an easy-cleaning coating by combining UV light curing technology and fluorine-containing silicone resin.
4、氟硅氧烷改性的聚酯树脂的耐热性和表面性能,Surface
在这项工作中,报道了由具有优异的耐热性和表面润湿性的聚酯(PET)和氟硅氧烷树脂(FS)制备的氟硅氧烷改性的聚酯树脂(FSP)。 通过1H,1H,2H,2H-全氟烷基三乙氧基硅烷(FTEOS),甲基三乙氧基硅烷(MTEOS),苯基三乙氧基硅烷(PTEOS),二甲基二甲氧基硅烷(DMDMOS)和二苯基二甲氧基硅烷(DPDMOS)的水解和缩合反应合成FS。 通过傅立叶变换红外(FT-IR),X射线光电子能谱(XPS)和原子力显微镜(AFM)确定树脂的表面化学组成和形态。 分别通过接触角测量和热重分析(TGA)研究了FPS膜的表面润湿性和热性能。 改性树脂显示出优异的耐热性,由于氟硅氧烷具有天然的高键能和低表面自由能,因此具有拒水和拒有 …
5、Types of Fluorosilicone Resin
Fluorosilicone Modified Organosilicon Resin: After modifying organosilicon resin with organofluorine resin, the fluorosilicone resin combines the excellent properties of both resins.
Modification of Epoxy Coatings with Fluorocontaining Organosilicon
In this work, we have synthesized a number of organosilicon copolymers and studied their compatibility with epoxy matrix and hydrophobic efficiency. It was shown that the increase of phenyl-containing units leads to increase of compatibility but decreases hydrophobic efficiency.
纳米SiO 2 /含氟硅防水透湿整理剂的制备及其应用
In order to improve the waterproof and moisture-permeable properties of polyester fabrics, a semi-continuous seed emulsion polymerization method was adopted, where acrylate monomers were used as polymerized monomers, nano-SiO 2, dodecafluoroheptyl methacrylate (G04) and vinyl trimethoxy using silane (A-171) as functional monomer.
Fluorine
In this paper, a waterborne acrylic coating (fluorine-silicon/N+ polyacrylate) with the chemically bonded antibacterial constitutional units have been successfully synthesized via simple soap free emulsion polymerization.
Synthesis and Properties of Modified Fluorosilicone
Abstract A quaternary ammonium salt functionalized fluorosilicone polymer (KFQ) was synthesized by free radical telomerization of 3-mercaptopropyl trimethoxysilane (KH590), (perfluorohexane) ethyl methacrylate (C6MA) and methacryloxyethyl dimethyl dodecyl ammonium bromide (QDEMA). The polymer (KFQ) was further grafted to poly (dimethylsiloxane) (PDMS) and formed a thermodynamically driven ...
A kind of organosilicon organofluorine modified acrylic acid heavy
[0018] A kind of organosilicon organic fluorine modified acrylic heavy-duty anticorrosion coating described in this embodiment, it is made of the barium sulfate that contains weight ratio 500g fluorosilicon modified acrylic resin, 120g titanium dioxide, 8g carbon black, 5g iron oxide red, 100g, 50g Calcium carbonate, the mixture of 4g foam ...
In the field of modern materials science, organic resins—an important class of polymeric materials—are widely used in industries such as electronics, construction, and automotive engineering due to their unique physicochemical properties and excellent mechanical performance. with continuous technological advancements and expanding application fields, higher demands have been placed on the performance of organic resins, particularly in terms of temperature resistance, corrosion resistance, and electrical insulation. To address these challenges, scientists have begun exploring the integration of fluorosilicon elements into organic resins to enhance their properties. This process not only involves fundamental principles of materials science but also requires interdisciplinary collaboration. This article discusses the concept of fluorosilicon-modified organic resins, their advantages and challenges in practical applications, and future development trends.
Fluorosilicon-modified organic resins are novel materials formed by combining fluorosilicon compounds with organic resins. By introducing fluorosilicon elements, these composites exhibit a range of superior properties, including exceptional temperature resistance, corrosion resistance, and electrical insulation. These enhanced performances have unlocked significant potential for fluorosilicon-modified organic resins in fields where traditional materials fail to meet requirements.
First, the temperature resistance of fluorosilicon-modified organic resins has been substantially improved. Due to the low melting points and excellent thermal stability of fluorosilicon compounds, they effectively enhance the heat resistance of organic resins. This enables the materials to maintain robust performance in high-temperature environments, making them suitable for aerospace, automotive, and other demanding sectors.
Second, the corrosion resistance of fluorosilicon-modified organic resins has been greatly enhanced. Fluorosilicon compounds possess superior chemical stability, capable of withstanding erosion from acids, bases, salts, and other chemicals. This characteristic expands their application prospects in industries such as chemical engineering and petroleum.
Additionally, fluorosilicon-modified organic resins demonstrate outstanding electrical insulation properties. Fluorosilicon compounds form stable fluoride structures, providing reliable electrical insulation. This quality makes them highly valuable in electronics and electrical equipment.
despite these advantages, fluorosilicon-modified organic resins face limitations, including high costs and complex preparation processes. These factors restrict their widespread adoption in certain fields. reducing costs and optimizing production techniques are critical to enabling broader applications.
To overcome these challenges, scientists are actively exploring new synthesis methods and manufacturing processes. For instance, improving reaction conditions, adopting green solvents and catalysts, and optimizing production workflows can help lower costs. Additionally, scaling up production could further reduce expenses.
Beyond cost and processing issues, compatibility and mechanical performance also impact the practical use of fluorosilicon-modified organic resins. Enhancing compatibility requires selecting appropriate fillers and additives to meet specific performance needs. Mechanical properties can be improved by adjusting molecular structures or incorporating toughening agents.
Looking ahead, fluorosilicon-modified organic resins are poised for expanded applications. With ongoing technological advancements, it is reasonable to anticipate further performance enhancements and broader utility across diverse sectors.
fluorosilicon-modified organic resins represent a novel material with exceptional properties, offering new opportunities for modern materials science. Through continuous technological innovation and optimization, these resins are expected to play an increasingly vital role in future scientific and industrial progress.
