软段含离子的含氟水性聚氨酯的制备

以单羟基氟碳链一元醇为有机氟改性剂,将含氟基团引入聚氨酯主链中,通过分子设计的方法制备出软段含有离子基团的有机氟阴离子型水性聚氨酯。 比较了传统水性聚氨酯、硬段含氟的水性聚氨酯和软段含氟的水性聚氨酯在合成方法、耐水性、 热稳定性以及结晶性方面的差异;实验证明了软段含氟聚氨酯的水性聚氨酯的性能最为优良。 通过红外光谱的表征确定了氟化聚氨酯的结构,并证明了含氟基团的引入对聚氨酯软硬段间氢键作用的影响;水接触角由73°增加至107°,吸水溶胀率降低了66%,胶膜耐水性提高;热重分析结果表明,含氟聚氨酯的最大热失重温度提高了30 ℃,热稳定性增加;广角X射线衍射结果表明,胶膜的结晶度增加,结晶形式发生了微小程度的转变;扫描电子显微镜结果证明存在不均匀的多相结构。     

聚含氟丙烯酸酯-聚氨酯三嵌段共聚物水基分散体的合成及膜结构

聚含氟丙烯酸酯-聚氨酯三嵌段共聚物水基分散体的合成及膜结构;含氟丙烯酸酯;水性聚氨酯分散体;表面结构;核壳分散体     

含氟聚氨酯的研究进展

综述了溶剂性、水性含氟聚氨酯的合成及研究，并进行了讨论。     

含氟聚氨酯

(有关国外文献概述) 一九五八年英国专利首次报导了含氟聚氨酯的合成。六十年代国外对含氟聚氨酯进行了较广泛深入的研究。在美国,以国家宇宙航空局(NASA)为中心,在Narmco,3M.以及dupont等公司中进行了这方面的研究。在苏联,乌克兰高分子研究所等单位也进行了研究。Narmco.公司,为探索耐液氧和在纯氧中不燃的新材料,从一九六三年开始,合成了数种新的含氟聚酯二醇,聚醚二醇以及含氟二异氰酸酯,并在此基础上合成了一系列含氟聚氨酯。据初步统计,现已研究的含氟聚氨酯达五、六十种之多。含氟聚氨酯已成为聚氨酯的一个分支,也已成为含氟高聚物中的一个独立研究方向。     

二维材料改性水性聚氨酯防腐涂料的研究进展

水性聚氨酯涂料作为一种新兴的环保涂料,在防腐领域得到了广泛应用。然而,水性聚氨酯涂料交联密度低,耐水性稍差,不利于其长效防腐性能。利用具有独特物理化学特性的二维材料作为水性聚氨酯的填料,可以有效改善其性能。本文主要介绍了三种二维材料(石墨烯、MXene和六方氮化硼)作为填料与水性聚氨酯进行复合,并重点介绍了石墨烯、MXene和六方氮化硼的改性方法,并对水性聚氨酯复合涂层的性能进行了阐述和比较,最后对未来二维材料/水性聚氨酯的复合材料的发展和应用进行了展望。     

水性聚氨酯涂料改性研究进展

随着环保理念的日益增长,水性涂料将逐步取代溶剂型涂料.水性聚氨酯涂料由于其综合性能优越,是水性涂料中发展最快的品种之一,得到了广泛研究.为了进一步提高水性聚氨酯涂料的性能,通常要对聚氨酯树脂进行改性.对近些年常用的改性技术,如有机树脂改性、无机纳米材料改性和植物油改性的原理与方法进行了综述.这些改性技术可以提高水性聚氨酯的耐热性、耐水性、光泽度、物理机械性能、固含量等综合性能.     

聚氨酯-丙烯酸酯杂化乳液结构与性能的影响

以聚四氢呋喃醚二醇（PTMG）、异氟尔酮二异氰酸酯（IPDI）、亲水单体二羟甲基丙酸（DMPA）,乙二胺为主要原料,制备了稳定的水性聚氨酯乳液.然后以苯乙烯（St）、丙烯酸丁酯（BA）为单体,过硫酸钾为引发剂,在不外加乳化剂的条件下,运用物理共混、化学复合和化学共聚三种方法对该水性聚氨酯乳液进行改性研究.用FTIR技术对聚氨酯-丙烯酸酯杂化乳液的结构进行了对比与表征;通过粘度测定、粒度分析、力学性能和耐水性能测试、DSC分析,研究了不同改性方法对乳液及其胶膜性能的影响.结果表明,化学共聚的改性方法对原水性聚氨酯的耐水性的改良效果最好,能够得到稳定且综合性能较优的聚氨酯-丙烯酸酯杂化乳液.     

可用于建材防水涂料的含氟聚氨酯的研制及性能研究

以聚醚二元醇和异氰酸酯合成两端含异氰酸酯基的聚氨酯预聚物,将含氟醇与聚氨酯预聚物进行反应,得到端基含氟的聚氨酯,制备了一系列含氟聚氨酯涂料。对涂料的性能研究显示,聚合物对基材具有良好的附着力,且随着含氟量的增大,制备的含氟聚氨酯涂层对水及乙二醇的接触角数值逐渐增大,表面能和吸水率逐渐降低;聚合物体系均一,未发生相分离。表明通过化学方法将含氟链段引入聚氨酯结构,得到了稳定的含氟聚氨酯聚合物,且涂料的表面性能得到提高。该含氟聚氨酯在建材防水涂料领域有广阔的应用前景。     

全氟烷基乙烯基醚合成的研究进展

全氟烷基乙烯基醚(PAVE)作为含氟单体,与含氟烯烃发生共聚,得到具有特殊功能的有机高分子材料,广泛用于含氟塑料、含氟橡胶和功能材料等领域。在合成方法上,主要包括直接热解法、催化热解法、Zn还原法、加氢脱氯法和含氟砌块法,通过分析这些方法的特点,认为催化热解法和含氟砌块法是比较有应用前景的两种方法。     

聚丙烯酸酯改性水性聚氨酯的制备

在回顾聚丙烯酸酯改性水性聚氨酯的研究历史基础上，系统地介绍了聚丙烯酸酯改性水性聚氨酯乳液（PUA）的制备方法，其中包括聚氨酯（PU）和聚丙烯酯（PA）的直接掺混法、PU和PA的乳液共聚法，接枝法，互穿网络法，核壳聚合法，对这些方法做了简单的评述，对其应用范围及前景进行了初步探讨。     

SURFACE STRUCTURE AND BULK PROPERTIES OF FLUORINATED POLY(ETHER URETHANE)S AND POLY(ETHER URETHANE) BLENDS

INTRODUCTIONPolyurethanes (PU) have been widely used for manufacturing medical devices because of their excellentmechanical properties and moderate biocompatibility[1]. Although polyurethanes used in applications requiringall of the above properties have been successful for short-term use, the problems of long-term thromboresistanceand biostability in a biological environment still remain unsolved[2,3]. A legitimate approach to improving theproperties of polyurethanes is introduction of f…     

硬段侧链含有氟化双季铵盐的聚氨酯表面性能及抗菌性能分析

研究了硬段侧链含有氟化双季铵盐的系列聚氨酯(FQPUs)的表面性能和抗菌性能. 水接触角测试和表面自由能测试结果表明, 加入少量氟化双季铵盐扩链剂, 可以使聚氨酯表面富集氟碳链, 氟化双季铵盐聚氨酯表面自由能很低, 具有很好的抗黏附性能. 迁移到表面的两条氟碳链在常温下不会发生链反转, 使材料的抗黏附性能得以保持. 同时, 使材料表面形成一层疏水层, 减小材料的吸水率. XPS研究结果表明, 氟碳链的-CF₃位于材料的最外层, 材料的次表面是具有良好杀菌性能的双季铵盐, 这样形成了具有多重抗菌性能的表面. 另外, XPS研究结果表明, 材料表面化学结构与材料本体的微相分离结构相关. 抗菌性能测试结果表明, 氟化双季铵盐聚氨酯抗金黄色葡萄球菌的能力很强, 对于大肠杆菌的抗菌效果有所下降, 但相对于单季铵盐聚氨酯的抗菌效果有一定提高.     

Preparation of an environmentally friendly antifouling degradable polyurethane coating material based on medium-length fluorinated diols

A novel medium-length fluorinated diols and poly(L-lactide) (PLLA) were synthesized via Michael addition reaction and ring-opening polymerization, respectively. Subsequently, Synthetic medium-length fluorinated diols and PLLA were combined to prepare new polyurethane composites with degradability and low surface energy. The compositional analysis and structural characterization of synthetic materials were characterized by using fourier transform infrared spectroscopy (FT-IR) and proton nuclear magnetic resonance spectra (¹HNMR). Thermogravimetric analysis(TGA) indicated that the introduction of medium-length fluorinated diols improved the thermal stability of the polyurethane. The biodegradation and low surface energy of the polyurethane were investigated by static hydrolysis experiment and water contact angle test. It was found that the degradation rate of the polyurethane increased as measurement time went on when the PLLA content was under 40%, and the water contact angle increased from 71.12° to 108.24° with the increase of fluorine content, which indicated that the degradable and low surface energy polyurethane has a potential as a coating material for a marine antifouling coating application.     

Synthesis and characterization of fluorinated polyurethane with fluorine-containing pendent groups

A novel fluorinated polyurethane （FPU） with fluorine-containing pendent groups was prepared by using fluorinated polyether glycol （PTMG-g-HFP） as a soft segment, 1,6-hexamethylene diisocyanate （HDI） or toluene diisocyanate （TD1） as a hard segment and 1,4-butanodiol （BDO） as a chain extender. FTIR, ^1H NMR, ^13C NMR and GPC were used to characterize the structure of the fluorinated polyurethane. Thermal stabilities of the fluorinated polyurethane and the corresponding hydrogenated polyurethane were studied by TGA. XPS analysis at two different sampling depths for the fluorinated polyurethane was used to investigate the surface compositions of FPU. The results showed the fluorine enrichment on the surface of FPU.     

Synthesis, characterization and properties of a novel fluorinated polyurethane

A novel fluorinated polyurethane (FPU) was prepared by fluorinated polyether glycol (PTMG-g-HFP) as a soft segment, 1,6-hexamethylene diisocyanate (HDI) or toluene diisocyanate (TDI) as a hard segment and 1,4-butanodiol (BDO) as a chain extender. Fourier transform infrared spectroscopy (FTIR), ¹H NMR, ¹³C NMR and gel permeation chromatography (GPC) were used to characterize the structure of the fluorinated polyurethane. The thermal stabilities of the fluorinated polyurethane and the corresponding hydrogenated polyurethane were studied by thermogravimetric analysis (TGA). X-ray photoelectron spectroscopy (XPS) analysis at two different sampling depths for the fluorinated polyurethane was used to investigate the surface compositions of FPU. And the mechanical properties of the fluorinated polyurethane and the corresponding hydrogenated polyurethane were also measured. Chemical resistance of polyurethane films was estimated through spot tests with different solvents. The results showed that FPU had high thermal stability, strain-hardening property and good chemical resistance. The XPS measurements showed the fluorine enrichment on the surface of FPU.     

Convenient synthesis of novel fluorinated polyurethane hybrid latexes and core-shell structures via emulsion polymerization process with self-emulsification of polyurethane

Novel fluorinated polyurethane hybrid latexes in the size range of 40–50 nm, fluoroalkyl acrylate as fluorinated monomers, with various fluorine content (F% = 9∼26 wt%) were successfully prepared via emulsion polymerization process without traditional emulsifier. The waterborne polyurethane, which was synthesized by using isophronediisocyanate, dimethylol propionic acid, polyethylene glycols, etc., served not only as copolymerizable macromonomer but also as polymeric high molecular weight emulsifier. The structures of polyurethane macromonomer and fluorinated polyurethane were characterized by Fourier transform infrared and H¹-NMR. Particle size, zeta potential, micromorphology of the latex par.ticles, and surface properties were investigated by dynamic light scattering, potential particle size analyzer, transmission electron microscopy, and contact angle measurement, respectively. Results illustrated that the advantage of this process is that the size of fluorinated polyurethane hybrid particle is less sensitive to the composition. Furthermore, it was showed that fluorinated polyurethane latex particles had core-shell structures, especially when the content of fluorine was 26.08 wt%. Moreover, there was an obvious migration of fluorinated groups to the surface during the formation of fluorinated polymer films, although fluorinated groups were covered by polyurethane in latex particles.     

Synthesis and characterization of fluorinated polyurethane containing carborane in the main chain: Thermal,mechanical and chemical resistance properties

In this study, two fluorinated polyurethanes(FPU) containing carborane groups in the main chains were firstly designed and synthesized via the reaction of hexamethylene diisocyanate trimer(HDI trimer) with fluorinated polyesters(CFPETs) having hydroxyl-terminated carborane groups at room temperature. The structures of carborane fluorinated polyesters(CFPETs) and polyurethanes(CFPUs) were characterized by gel permeation chromatography(GPC), Fourier transform infrared(FTIR) spectroscopy and nuclear magnetic resonance(NMR) measurements. The thermal stability, mechanical properties, Shore A hardness, solvent resistance and acid-alkali resistance of the carborane fluorinated polyurethane films were also studied. Thermogravimetric analysis(TGA) tests manifested that the introduction of carborane groups into the main chain of fluorinated polyurethane endowed the obtained fluorinated polyurethane with excellent thermal stability. The thermal decomposition temperature of carborane fluorinated polyurethane(CFPU) increased by 190 °C compared with that of the carborane-free fluorinated polyurethane(FPU). Even at 800 °C, CFPU showed the char yield of 66.5%, which was higher than that of FPU(34.3%). The carborane-containing fluorinated polyurethanes also showed excellent chemical resistance and prominent mechanical property even after the cured films being immersed into Jet aircraft oil or 37% HCl for 168 h or at high temperature(700 °C). It is found that the structural characteristics of carborane group and the compacted structure of CFPU effectively improve the thermal stability, mechanical property, solvent resistance and acid-alkali resistance of the carborane-free fluorinated polyurethane. These excellent properties make CFPU as the useful raw materials to prepare the high temperature resistant coatings or adhesives for automotive engines, engine or fuel tank of aircraft and other equipment working in high-temperature or high concentrations of acid-alkali environments.     

A novel approach to fluorinated polyurethane by macromonomer copolymerization

For the first time, through macromonomer radical copolymerization, a novel fluorinated polyurethane (FPU) was synthesized based on partly acrylate-endcapped polyurethane macromonomers with hexafluorobutyl acrylate (HFBA). Partly acrylate-endcapped polyurethane (PU) macromonomers were synthesized using isophronediisocyanate (IPDI), dimethylol propionic acid (DMPA), polyethylene adipate glycols (PEA) etc. The novel fluorinated polymer, which bore PU side chains and fluorinated side chains, was confirmed by F¹⁹ NMR spectroscopy, X-ray photoelectron spectroscopy (XPS), elemental analysis, scanning electron spectroscopy (SEM) etc. Copolymerization of polyurethane macromonomers with hexafluorobutyl acrylate (HFBA) was briefly investigated. The surface tension of FPU solution was measured and showed sharply decrease compared to that of pure polyurethane. Results from SEM showed a uniform size distribution of phase micro-domains on the fracture surface of FPU.     

Preparation, characterization and application of polymeric diols with comb-branched structure and their nanocomposites containing montmorillonites

The polymeric diols with comb-branched structure (CPD) and their nanocomposites containing montmorillonites (MMT) were prepared through three-step reaction on basis of molecular design. The effect of experimental parameters, such as molar mass of oligomer polyols, catalysts and MMT on conversion of -NCO group during polymerization was investigated by utilizing FTIR to measure content of -NCO group varied as reaction time. In addition, the structure of comb-branched polymeric diols was characterized by FTIR and ¹H NMR. The results show that the comb-branched chains contain reactive CC double bonds in CPD. The nature of dispersion of montmorillonites in CPD was characterized by X-ray diffraction. The results show that Na⁺-MMT is exfoliated and organo-MMT is intercalated in CPD via in-situ polymerization. Finally, the properties of water-borne polyurethane modified with CPD or CPD/2T-MMT nanocomposite were compared with those of common water-borne polyurethane, and the comb-branched chains and 2T-MMT improve the properties of water-borne polyurethane.