聚偏氟乙烯涂料的研究

用聚偏氟乙烯(PVDF)树脂制备了溶剂型氟碳涂料,筛选并优化了PVDF涂料的溶剂组成。采用丙烯酸树脂对PVDF进行改性,并研究颜填料钛白粉对涂膜性能的影响。结果表明,由甲苯、甲基异丁基酮、乙二醇乙醚乙酸酯、2,2,4-三甲基-1,3-戊二醇单异丁酸酯及邻苯二甲酸二甲酯组成的溶剂体系的涂料综合性能比较好,而丙烯酸树脂和钛白粉的加入明显地改善了PVDF涂膜的性能。     

生漆/氨基硅氧烷/环氧桐油复合涂料的 制备与性能研究

以生漆为原料,先采用γ-氨乙基氨丙基三甲氧基硅烷(AATMS)与漆酚的酚羟基发生醇解反应,再通过AATMS的氨基与环氧桐油的环氧基发生开环反应,得到了一种复合涂料。该涂料的干燥成膜过程是在漆酶作用下,通过空气自氧化聚合得到高度交联的聚合膜。固定AATMS用量为生漆质量分数10%不变,讨论了环氧桐油用量对生漆的物理机械性能的影响,结果发现环氧桐油用量为生漆质量分数的30%时,漆膜的性能最佳,柔韧性、耐冲击性、硬度、附着力分别提高到2mm、40kg·cm-1、6H和1级。利用红外光谱分析(FT-IR)证实了复合涂膜的结构。利用热分析(TG-DTG)研究了复合涂膜和生漆涂膜的热稳定性,结果表明复合涂膜比生漆涂膜的热稳定性高。研究测试了复合涂膜和生漆涂膜的耐溶剂性能、耐化学介质性能和耐老化性能,结果表明复合涂料的漆膜比生漆涂膜性能都大幅提升。     

粘度法研究氯化聚丙烯和涂料树脂间的相容性

用稀溶液粘度法研究了氯化聚丙烯与石油树脂、丙烯酸树脂和醇酸树脂间的相容性,并用α判据对相容性结果进行判别。结果显示,石油树脂/氯化聚丙烯的共混体系是相容的;丙烯酸树脂/氯化聚丙烯的共混体系是不相容的。而醇酸树脂与氯化聚丙烯的相容性情况复杂,由二者的组成决定。当m(醇酸树脂)∶m(氯化聚丙烯)1∶1时,体系是相容的;当m(醇酸树脂)∶m(氯化聚丙烯)1∶1时,体系是不相容的。通过共溶剂法和涂膜宏观特性对上述体系的相容性进行测定,所得结果与α判据的结果相符合,印证了稀溶液粘度法研究溶液中高分子间的相互作用来预测涂料树脂的相容性具有一定可行性。     

氟硅协同改性丙烯酸树脂的合成与防污性能研究

以甲基丙烯酸十二氟庚酯(FMA)、甲基丙烯酸聚二甲基硅氧烷基酯(SMA)、甲基丙烯酸甲酯、丙烯酸正丁酯、甲基丙烯酸正丁酯和丙烯酸乙酯为共聚单体,通过溶液聚合反应合成出侧链含有机氟、有机硅的丙烯酸树脂.通过核磁共振氢谱(1H-NMR)、核磁共振氟谱(19F-NMR)、红外光谱(FTIR)对聚合物的结构进行了表征.通过扫描电镜(SEM)、接触角测试和生物评价等方法,探讨了FMA、SMA含量对树脂涂膜性能的影响.结果表明氟硅改性的丙烯酸树脂比单独含氟或含硅改性的丙烯酸树脂具有更低的表面能,而且氟硅改性的丙烯酸树脂涂膜比商业化的聚硅氧烷涂膜具有更好的防污性能.     

超支化树脂改性UV固化粉末涂料

本文将超支化树脂(HBP)与UV固化粉末涂料相结合,研究了超支化树脂对该涂料的树脂体系玻璃化温度、流变性能及涂膜各项物理性能的影响.结果表明:添加改性与未改性超支化树脂都能降低树脂体系的玻璃化温度,改性超支化树脂不影响体系的流变性能及涂膜性能,未改性超支化树脂可以降低体系粘度但使涂膜性能变差.     

化学改性环氧树脂水基涂料的研究——涂膜性能

用对氨基苯甲酸改性环氧树脂 ,使其具有亲水亲油两亲性质 ,测定了改性产物和纯环氧树脂共混物的玻璃化转变温度 ,结果显示两者能够相容 ,并以改性产物及其与纯环氧树脂的混合物制备水基涂料 ,测定了涂膜的物理和化学性能。结果表明 ,涂膜性能优良 ,保持了溶剂型环氧涂料的抗冲击强度、光泽度和硬度等方面的优点 ,而附着力提高 ,同时柔韧性大为改善 ,涂膜耐水性和耐化学药品性能优良。     

漆酚醛缩聚物/丙烯酸树脂IPN涂料的制备及性能

漆酚醛缩聚物/丙烯酸树脂IPN涂料的制备及性能;漆酚甲醛缩聚物;丙烯酸树脂;互穿聚合物网络;涂料     

涂料用可交联聚丙烯酸酯乳液的研究进展

对涂料用可交联丙烯酸乳液的制备方法,组成、结构与乳液及涂膜性能的相互关系和各种乳液体系的交联机理作了较详细的综述。     

苯乙烯和丙烯酸系改性醇酸树脂涂料

综述了苯乙烯和丙烯酸系改性醇酸树脂的研究进展,介绍了该类树脂的合成、性能及应用,讨论了该类树脂的优缺点,预测了苯乙烯和丙烯酸系改性醇酸树脂涂料的发展趋势。     

涂料用可交联聚丙烯酸酯浮液的研究进展

对涂料用可交联丙烯酸乳液的制备方法,组成,结构与乳液及涂膜性能的相互关系和各种乳液体系的交联机理作了较详细的综述。     

Properties of nitrocellulose‐coated and polyethylene‐laminated chitosan and whey films

Chitosan (chitosan acetic acid salt) and whey (65% protein) films were coated with a nitrocellulose lacquer or laminated with polyethylene to enhance their water resistance and gas barrier properties in humid environments. The barrier properties were measured by the Cobb₆₀ test and water‐vapor (100% relative humidity) transmission and oxygen (90% relative humidity) permeability tests. Mechanical properties were obtained with tensile tests. Packaging properties were studied with crease and folding tests. The Cobb₆₀ test revealed that the coated films were resistant to liquid water, at least for a short exposure time, if the coating thickness was at least 10–17 μm. Water‐vapor transmission rates comparable to those of polyethylene‐laminated films were obtained for coated chitosan at a coating thickness of 5–7 μm. The coated films possessed low oxygen permeability despite the high humidity. Coated films dried for 3 weeks showed oxygen permeabilities at 90% relative humidity that were similar to values for dry ethylene‐co‐vinyl alcohol at 0% relative humidity. The lacquer partly penetrated the whey films, and this led to excellent adhesion but poor lacquer toughness. The lacquer coating on chitosan was tougher, and it was possible to fold these films 90° without the coating fracturing if the coating thickness was small. The coated whey films were readily creasable. © 2001 John Wiley & Sons, Inc. J Polym Sci B: Polym Phys 39: 985–992, 2001     

添加改性松香对生漆漆膜性能的影响

通过添加松香、改性松香对生漆漆膜进行改性,研究结果表明,加入改性松香能改善生漆漆膜性能,在反应温度为80℃时,加入生漆质量5％的聚合松香效果最佳,附着力为1级,抗冲击力为35kg／cm,铅笔划痕为3H。反应温度对漆膜性能有很大影响,当加入生漆质量5％的聚合松香,反应温度从50℃升至80℃时,附着力从3级提高到1级,抗冲击力从10kg／cm提高到35kg／cm,铅笔划痕从H升至3H。红外光谱分析表明,天然松香对生漆性能的增强效果是由于与生漆发生了化学反应,而聚合松香对生漆性能的增强效果是协同作用造成的。     

Structural study of oriental lacquer films during the hardening process

Oriental lacquer is the natural resin obtained by tapping lac trees. It hardens into a tough and insoluble film. The extreme hardness and insolubility are some of the most important functions, which are required for industrial coating materials. In this study, two kinds of oriental lacquer films, traditionally named Kiurushi (raw urushi) and Kuromeurushi produced by two different pretreatments, were analyzed during hardening with Fourier transform infrared spectroscopy (FT-IR), thermogravimetry/differential thermal analysis-mass spectrometry (TG/DTA-MS) and pyrolysis-gas chromatography/mass spectrometry (Py-GC/MS) to investigate their functional expression process. Typical functional groups of the lacquer films were detected by FT-IR. The TG/DTA-MS curves clarified that the thermal degradation of the lacquer films gradually began at around 200 °C, and reached the fastest rate at 400-500 °C. Apparently, FT-IR and TG/DTA-MS could not reveal any difference between the films. On the other hand, Py-GC/MS revealed differences between the films in the peak area ratios of 3-pentadecenylcatechol to 3-pentadecylcatechol and 3-pentadecadienylcatechol to 3-pentadecylcatechol. The ratios of Kiurushi lacquer film were higher than those of Kuromeurushi lacquer film. Both ratios, furthermore, decreased during hardening due to polymerization of the alkenylcatechols into an urushiol polymer skeleton comprising nucleus-side chain and side chain-side chain cross-linkages with 3-pentadecylcatechol at the terminal. The present results suggest that the reaction rate of these cross-linkages in Kuromeurushi lacquer film is faster than that in Kiurushi lacquer film. A good correlation was found between the peak area ratios obtained by Py-GC/MS and hardness obtained by pencil hardening testing. Oriental lacquer expresses the functions - an extreme hardness and insolubility - accelerating the nucleus-side chain and side chain-side chain cross-linkages. Furthermore, it has become clear that the traditional treatments called Nayashi and Kurome effectively accelerate the hardening rate by activating the cross-linkages.     

Elektrotauchlackierung

The principle of the electro‐dip‐coating is based on the discharge of polymer‐ions and subsequent film formation. A subsequent oven‐burning with physical film‐formation and chemical crosslinking leads to an outstanding corrosion‐protection and further chemical and mechanical qualities. The extremely uniform layer thickness even in cavities is founded on the increasing electric resistance of deposited and condensed lacquer‐material on the metal‐surface.     

漆酚铁聚合物的制备及性能研究

以生漆和三氯化铁反应制备漆酚铁聚合物,用红外光谱、涂膜鲜映性仪和光泽度仪等对聚合物结构和漆膜性能进行表征.结果表明,反应温度65℃,反应时间3h,漆酚和三氯化铁物质的量比为8∶1,所生成的漆酚铁聚合物性能较好.     

新型PA/PU复合涂料的合成与性能研究

合成了一种高固含量、不含异氰酸根并可在室温固化的新型聚丙烯酸酯－聚氨酯复合涂料（简写为ＰＡ－ＰＵ），其中ＰＡ为侧基含乙酰乙酸基的聚丙烯酸酯，ＰＵ为端烯基聚氨酯。碱催化下，通过具有两个活泼氢的乙酰乙酸基与双键的Ｍｉｃｈａｅｌ加成反应进行交联固化。主要研究了两组份的合成规律及ＰＡ－ＰＵ涂料的性能，结果表明在一定的催化剂用量下，漆膜具有优良的性能     

Deterioration of surface structure of lacquer films due to ultraviolet irradiation

The mechanism of deterioration due to ultraviolet irradiation of black (with iron ion) and kurome (translucent) lacquer films that had been dried at 15–20 °C in 60–70% relative humidity environment was revealed. The lacquer film changes were evaluated by observations of the surface by microscopy, IR, and XPS. A particulate material and toroidal shapes appeared in the black lacquer film during UV irradiation within 48 h, but they did not appear in the kurome lacquer film under UV irradiation before 240 h. The IR peak at ～3445 cm^?1 increased owing to the hydroxyl group, and the C 1s peak decreased and O 1s increased in the XPS spectra as the UV irradiation time increased, implying that a chemical reaction occurred on the surface of the lacquer film. On the top surface of the coating film, many toroidal shapes were observed in the black lacquer film, which showed that the black lacquer film deteriorated more quickly than the kurome lacquer film. In addition, the structural changes in the black lacquer film are also discussed in detail, on the basis of the results of the Py‐GC/MS measurement. Copyright © 2006 John Wiley & Sons, Ltd.     

Effect of the feeding mode of cross-linker and microcapsule on the corrosion resistance and hydrophobicity of composite coatings

The interface combination of anti-corrosive materials and polymer matrix has a significant effect on the overall performance of the composite coating. However, past research has focused on blending anti-corrosive materials to improve the performance of the polymer matrix. Herein, we proposed a layer-by-layer spray-coating process to further enhance the reinforcing effect of anti-corrosive materials on the polymer matrix by changing their feeding modes. In this paper, taking waterborne polyacrylate (WPA) as an example, two kinds of reinforcement materials commonly used to improve the corrosion resistance of polymer matrix were introduced into the coating system and then applied to the tinplate: cross-linker and microcapsule. Firstly, five types of WPA composite coating systems were designed according to the feeding mode of aziridine cross-linker and the position of benzotriazole@zinc oxide microcapsules (BTA@ZnO MCs). Electrochemical impedance spectroscopy (EIS) and electrical equivalent circuits were used to evaluate the corrosion resistance of these composite coating systems and analyze their electrochemical processes. By spraying the mixture of WPA and aziridine crosslinker as the bottom layer and BTA@ZnO MCs as the top layer, the resulting composite coating exhibited higher corrosion resistance and hydrophobic properties. Scanning electron microscope (SEM) and contact angle tests indicated that the feeding mode of aziridine cross-linker and the position of BTA@ZnO MCs played important roles in the compactness and hydrophobicity of the composite coating. Subsequently, the effects of the amount of aziridine cross-linker and BTA@ZnO MCs on the corrosion resistance and physical properties of the composite coating were further analyzed by EIS, water absorption test, contact angle test and atomic force microscopy (AFM). The significant improvement in the corrosion resistance of this composite coating was mainly attributed to the synergistic effect of highly cross-linked network structure and superhydrophobic surface.     

Eco-efficiency analysis of textile coating materials

Eco-efficiency is critical for organisations that seek to be both environmentally conscious and profitable. It helps to “produce more out of less” to avoid wasting natural resources and to reduce emissions and damage to the environment. The textile coating and laminating industry, utilising solvent or water-based polymeric mixtures, is one of the industries coming under extreme environmental pressure to replace traditional procedures and use eco-efficient coating agents. In this study, eco-efficiency analysis was used to compare the eco-effectiveness of two different coating agents, polyacrylate and polyurethane, each in organic solution as well as aqueous dispersion forms. The “ecological fingerprint” and eco-efficiency portfolio were graphically illustrated for these coating agents based on the customer benefit, defined as coating one square meter of a textile fabric in a conventional laminating unit. According to the analysis results, polyacrylate dispersion in water was the most eco-efficient coating agent whilst polyurethane resin dissolved in organic solvent was found as the coating agent with the least acceptability as an eco-efficient product.     

Advanced environmentally friendly anticorrosive materials prepared from water-based polyacrylate/Na-MMT clay nanocomposite latexes

A series of novel advanced environmentally friendly anticorrosive materials have been successfully prepared by effectively dispersing nanolayers of Na⁺-montmorillonite (Na⁺-MMT) clay into water-based polyacrylate latex (i.e., vinyl acrylic terpolymers). First of all, a polyacrylate latex was synthesized through co-polymerizing organic monomers of MMA, BMA and styrene (St) using conventional emulsion polymerization technique with SDS, 1-pentanol and KPS as surfactant, co-surfactant and initiator, respectively. Subsequently, the commercial purified hydrophilic Na⁺-MMT was effectively dispersing into the polyacrylate latex through the direct solution dispersion technique.The as-prepared neat polyacrylate and the series of water-based polyacrylate/Na⁺-MMT clay nanocomposite (Na⁺-PCN) materials were subsequently characterized by FTIR spectroscopy, XRD, TEM and GPC. The water-based Na⁺-PCN materials loaded with low content of Na⁺-MMT when in the form of coating on the cold rolled steel (CRS) coupons was found to be remarkably superior in anticorrosion efficiency over those of neat polyacrylate based on a series of electrochemical measurements of corrosion potential, polarization resistance, corrosion current, and impedance spectroscopy in saline. Effect of material composition on the molecular barrier, optical clarity and thermal stability were also studied by molecular permeability analysis, ultraviolet-visible transmission spectra, differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA), respectively. Organo-PCN materials were also prepared as a control experiment for comparative studies.